FR2573065A1 - Process and apparatus for the chemical conversion of natural seawater into a liquid for fertilisation of plants - Google Patents

Abstract

According to this process, the natural seawater is sent into one or more treatment vessels 1a, 1b, 1c, inside which the conversion of the chlorides, in solution in this water, to sulphates and/or to phosphates, and/or to nitrates, is carried out by addition of a sulphuric acid and/or a phosphoric acid, and/or a nitric acid. In each of these vessels, a swirling movement is imparted to the water to be treated during its circulation inside the treatment vessel(s). Ammonia is also injected near to the outlet from each treatment vessel, by means of injectors connected to pipes 18a, 18b and 18c. Finally, additives, such as potash, can be added to the fertilising solution thus obtained. This solution can be used for spraying soils for the purpose of cultivating plants of various kinds.

Description

 The present invention aims to make it possible to irrigate and fertilize insufficiently irrigated land, or not irrigated at all, in particular uncultivated or desert land, in order to allow the cultivation of plants there.

 Such irrigation currently raises a very difficult problem, if not impossible to solve in some cases, due to the remoteness of possible sources of water supply or the insufficiency of available reserves. This is why the invention proposes to solve this problem by having recourse to a source of supply whose reserves are practically inexhaustible, but which had not been able to be used until now, in this case: water sea whose chemical composition, based on chlorides, normally makes it unsuitable for plant life, apart from a few rare varieties of plants well suited to such a composition.

 To this end, the subject of the invention is both a method and an apparatus designed to ensure the chemical transformation of natural sea water into a liquid for fertilizing plants.

 The process according to the invention essentially consists in treating natural sea water, taken from the sea, by transforming the chlorides in solution in the treated water, into sulfates and / or phosphates, and / or nitrates by adding a sulfuric acid and / or a phosphoric acid and / or a nitric acid and by imparting a swirling movement to the water to be treated during its circulation inside the treatment enclosure (s).

 There is thus obtained a liquid suitable for allowing the cultivation of plants on irrigated land by means of it, since it is free of chlorides unfit for plant growth. In addition, it is a fertilizing liquid since it contains sulfates and plays phosphates and / or nitrates, which are excellent soil fertilizers.

 Preferably, ammonia is also added to neutralize the hydrochloric acid released during the reactions of transformation into sulfates, phosphates and nitrates, which gives an ammonium chloride constituting a fertilizer assimilable by plants.

As for the device according to the invention, it is specially designed for the implementation of the present process, therefore for the treatment of natural sea water with a view to its transformation into a fertilizing liquid. For this purpose, this device includes
a tubular treatment enclosure at the two ends of which are respectively connected a supply line for the sea water to be treated and a pipe for discharging the fertilization liquid obtained after treatment;
- opposite the inlet end of this tubular enclosure, an injection nozzle for the acid (s) (sulfuric acid, phosphoric acid, nitric acid) to be added to the treated seawater
- a helical stator arranged inside the tubular treatment enclosure and arranged near the inlet thereof to impart, to the seawater to be treated, a vortex movement during its circulation in the inside this enclosure.

 In a particular embodiment of the treatment apparatus according to the invention, it comprises a bundle of a series of treatment tubes arranged side by side to form a multi-channel system at the two ends of which are connected respectively a seawater supply pipe to be treated and a fertilization liquid discharge pipe obtained after treatment. In such a case, the inlet end of each of these tubes includes an injection nozzle for the acid (s) (sulfuric acid, phosphoric acid, nitric acid) to be added to the treated seawater.

Furthermore, inside the inlet of each of the treatment tubes, there is provided a helical stator capable of imparting a vortex movement to seawater during its circulation in each of these tubes.

However, other particularities and advantages of the apparatus and of the method according to the invention will appear during the following description given with reference to the appended drawing, in which
Figure 1 is a perspective view, broken away, of a first embodiment of a treatment chamber of the apparatus according to the invention;
Figure 2 is a similar view, on a different scale of an alternative embodiment;
FIG. 3 is a diagram of an installation comprising several treatment chambers of this type, connected one after the other;
FIG. 4 is a front elevation view, with parts broken away, of a unit for producing a treatment enclosure according to the invention;
FIG. 5 is a diagram of an installation comprising several treatment chambers according to FIG. 4;
Figures 6 and 7 are detail views in section.

 As already indicated, the method according to the invention consists in treating natural sea water taken from the sea to ensure, in a chemical manner, the transformation of the chlorides contained in this water, into sulfates and / or phosphates and / or nitrates to obtain a liquid capable of being used for soil irrigation and fertilizing plants. This transformation is ensured by double chemical decomposition of a weak acid by a strong acid to obtain salts which can be assimilated by all plants. To this end, sulfuric acid, phosphoric acid and nitric acid are added to the treated seawater to take advantage of the corresponding reactions.

 However, as in this chemical reaction there is release of hydrochloric acid, this one is neutralized, in a determined phase of the treatment, with ammonia in order to obtain ammonium chloride, which constitutes an excellent fertilizer .

 It is also advantageous to add potash to reduce excess acidity and enrich the potassium concentration that is too low in seawater. However, any other product that can reduce excess acidity and constitute a useful component for the fertilization of plants.

 The treatment according to the invention can be carried out continuously, in an apparatus such as that shown in FIG. 1. This apparatus consists of a tubular enclosure 1 traversed over its entire length by the seawater to be transformed. For this purpose two pipes (not shown) are connected respectively to the inlet end 2 of this enclosure and to its outlet end 3 to ensure the supply of natural sea water to be treated and the evacuation of the liquid obtained in direction of an area to be irrigated. In the inlet end 2 opens one or more injectors 4 intended to inject a determined acid into the seawater to be treated, this injector being connected at the end of a supply pipe 5.

 The inlet end 2 of this enclosure encloses a helical stator 6 capable of imparting a swirling motion to the water treated inside the enclosure 1. At an intermediate point of the length thereof, by example at 9/10 of this length, there is an injector 7 intended to ensure the addition of ammonia and which is connected at the end of a supply pipe 8.

 Thanks to the swirling movement imparted to the water to be treated, a perfect result is obtained for the transformation of the chlorides contained in sea water into sulfates, or phosphates, or even nitrates. In addition, there is no loss of matter, since the hydrochloric acid released by the chemical reactions is transformed into ammonium chloride, due to the injection of ammonia.

However, ammonium chloride is an excellent fertilizer.

 Instead of a treatment enclosure 1 comprising a helical stator 6, it is possible to use a treatment enclosure 10 containing a vortex 11 fixedly mounted at the end of an axis 12 so that its blades print with water of sea a swirling movement during circulation inside the enclosure 9. The latter also comprises, as before, an ammonia injector 14.

 When it is desired to obtain a fertilizing solution comprising three different salts - in this case: sulfate, phosphate and nitrate - it is advisable to use an installation such as that shown in FIG. 3. This comprises three treatment chambers 1a, 1b , lc, identical to enclosure 1 or 10, and which are connected in parallel to be supplied with seawater from a pipe 14 starting from a basin 15 and on which is mounted a suction pump 16 and delivery, valves 17a, 17b, 17c controlling the entry into each treatment enclosure.

In each of these opens an injector intended for
Inject one of the three acids desired, for example sulfuric acid in enclosure la, phosphoric acid in enclosure lb and nitric acid in enclosure lc.

 Each of these injectors is connected, via a line -respectively 8a, 8b and 8c-, to a reservoir 15a, 15b or 15c containing the corresponding acid. The discharge of this acid is ensured by air pressure from a pump 16, valves 17 controlling the inputs and outputs.

At some distance from the outlet of each enclosure, an ammonia injector opens, connected to an amnnicdz reservoir 18 The discharge of the latter is also ensured by air pressure from the pump 16 and in pipes 18a, 18b and 18c leading to the injectors opening into the chambers la, lb and lc.

 A pipe 19, connected to the output of the various enclosures, collects the various liquids resulting from the treatments carried out in the three enclosures 1a, 1b and 1c. Consequently, at the outlet of this line, a fertilizer liquid is collected in a tank or tank 20 containing, in suspension, both sulphates, phosphates and nitrates, as well as ammonium chloride.

This liquid may also contain additive products, such as potash, coming from a reservoir 21 connected by a pipe 22, to the terminal part of the pipe 20.

 FIG. 4 represents an embodiment of the treatment enclosure according to the invention which is designed to allow the treatment of a large volume of natural sea water. This enclosure 24 comprises a bundle of treatment tubes 25, which are arranged side by side.

The inlet ends 26 of these various tubes are connected to a distribution box 27 to which leads a pipe (not shown) for supplying natural sea water.

As for the outlet ends 28 of these tubes, they are connected to a discharge manifold 29 from which a discharge pipe leaves (not shown).

 As in the case of the single enclosure 1 of FIG. 1, an injector 30 opens into the inlet end of each treatment tube 25 to ensure the addition of the desired acid. At an intermediate point of these tubes, there is also provided an injector 31 capable of ensuring the injection of ammonia. Finally, the inlet end of each of these tubes contains a helical stator 32 capable of imparting a vortex movement to the column of water treated in each tube.

Thanks to the presence of a bundle of multiple treatment tubes, this device makes it possible to treat a very large volume of water. Due to this arrangement the chemical reaction is considerably accelerated compared to
wearing to that which would be obtained in a single enclosure
of treatment crossed by the same volume of water.

Depending on the nature of the soil to be fertilized, there
it is possible to produce only one salt, for example
sulfate by adding only sulfuric acid to the water
sea to be treated.

In case we want to get a solution
fertilizer containing several salts - in this case:
sulfates, phosphates and nitrates- it is appropriate
to use an installation comprising several enclosures
treatment, such as the enclosure 24 of FIG. 4. A
such an installation is shown in FIG. 5.

This installation includes three speakers
24a, 24b, 24c whose input boxes 27a, 27b, 27c are
connected to a tank 33 of natural sea water, however
that their outlet manifolds are connected to a pipe
outlet 34 leading to a reservoir 35 collecting the
fertilizing solution thus obtained.

The injection of each of the acids provided is ensured by means of a perforated tube 36 (see fiv. 6) placed in
line 37a, 37b, 37c supplying seawater to the enclosure
respective processing. This perforated tube is connected to a
tank 38a, 38b, 38c containing the corresponding acid.

Preferably a venturi 39 is arranged upstream of each
perforated acid injection tube, as well as a cone valve
trôle 40.

In the collector 29 of each enclosure of
treatment, there is a ramp 41 intended to ensure
ammonia injection (see fig. 7). These ramps are connected to a reser
see 43 containing ammonia. As in the installa
tion shown in Figure 3-, the injection of these various
products is carried out under air pressure from a
pump (not shown). It is the same for the injection
additive products in the terminal part of the pipe
34 from a reservoir 44. Finally, a pump 45 is provided at the outlet of each treatment enclosure. These pumps, as well as the input pumps 39, can be controlled by a program control installation.

 It is thus possible to vary at will the proportions of the quantities of seawater treated in each enclosure. It is also possible to vary the proportions of the salts obtained by proportioning the respective amounts of the acids injected into the treated seawater accordingly.

 The dimensions of the tubes of each treatment enclosure may vary. However, it should be taken into account that the chemical reaction is normally completed in 3 seconds for a flow rate of lm / sec, over a course of 3m, in the case where the diameter of the channels is of the order of 25 at 35 mm. However, the diameter of the treatment tubes can vary between 20 to 40 mm, for a length of 3 meters and a flow speed of lmXsec.

 As for the number of treatment tubes provided in the same enclosure, it varies according to the importance of the volume of water to be treated. In fact, the volumetric division of the water to be treated has no influence on the chemical transformation reactions.

 Since in such multiple treatment tube enclosures, the chemical transformation reactions obey the law of molecular weights, the quantities of chemicals introduced into the apparatus must be calculated with great precision. On this subject, it should be taken into account that the value of the average concentration of natural seawater in sodium chloride is 27 to 32g of Na Cl per liter. However, as this concentration is variable depending on the place of sampling, it is necessary to use the products used at the maximum degree of concentration whose molecular weight is perfectly known.

As a simple indication, the following examples may be cited of the quantity of products to be added to a volume of seawater of 100 liters a) for obtaining a monosodium phosphate
H3 Po4 at 100% = from 5.025 to 10,000 Kg
NH3 at 100% = from 0.871 to 1.500 Kg
KoH at 100 oO- = 0.150 to 0.350 kg b) to obtain a sodium sulfate
H2 So4 at 100 e = from 5.030 to 8,000 Kg
NH3 at 100% = from 0.871 to 1.500 Kg
100% KOH = 0.250 0.350 Kg c) to obtain a monosodium nitrate
100% HNo3 = 3,230 to 6,000 Kg
NH3 at 100% = 0.871 to 1.500 Kg
100% KOH = 0.200 to 0.280 kg
The application of the method according to the invention makes it possible to achieve a yield of 50 to 100 g of fertilizer products per liter of treated sea water and depending on the temperature at which the treatment is carried out. It is therefore an extremely high concentration, which has the advantage of allowing rapid fertilization and regeneration of desert areas. In addition, it should be observed that the chemical reactions applied, during the implementation of the present process, do not cause any damage to the bacterial flora and fauna which are contained in natural sea water and whose presence is very useful for soil fertilization. Moreover, the tests carried out made it possible to note excellent results with regard to the development of plants cultivated on a soil watered with the solution obtained by the process according to the invention.

This is the result of observations made in the context of cultivation trials carried out over a period of three years, in greenhouses and on land located in Charente
Maritime. At each start of the season, this ground has been prepared, not by adding to it usual fertilizers, but by watering it with a fertilizing solution obtained from natural sea water with the process according to the invention.

The seeding was carried out 3 days later and the seedlings, as well as the plants resulting therefrom, were then normally watered with natural fresh water, carrying out, once a month, a special watering with the fertilizing solution obtained with the method according to the invention. These trials focused on the cultivation of peas, tomatoes and carrots, and this made it possible to note an excellent development of the plants thus cultivated.

 However, the method according to the invention makes it possible to obtain almost unlimited quantities of liquid fertilization solution. The application of this process can therefore make it possible to irrigate and fertilize desert areas of very large areas that previously could not be cultivated.

 It goes without saying that the apparatus and installations for implementing the present process are not limited to the examples described. Thus in the case of installations with multiple treatment enclosures it would be possible to connect these in series and no longer in parallel as provided in FIGS. 3 and 5, provided that the quantities of acids injected into the first and the second enclosure are insufficient to cause a complete reaction involving all of the sodium chloride suspended in the treated seawater. the quantities of acid injected should therefore be determined to cause only partial reactions in each enclosure so that the fertilizing solution thus obtained contains at the same time phosphates, sulphates and nitrates.

Claims (1)

CLAIMS 1 ") - Process for the chemical transformation of natural seawater into a plant fertilizing liquid, characterized in that natural seawater is continuously sent into one or more treatment chambers at inside which the chlorides, in solution in this water, are transformed into sulfates and / or phosphates, and / or nitrates, by addition of a sulfuric acid and / or a phosphoric acid, e / or a nitric acid, and by imparting a swirling movement to the water to be treated during its circulation inside the treatment enclosure (s). 2 ") - Method according to claim 1, characterized in that at treated seawater, ammonia is also added to reduce the hydrochloric acid released during the reactions of transformation into sulfates and phosphates, which gives an ammonium chloride constituting a fertilizer assimilable by plants. 3) - Method according to one of the preceding claims, characterized in that the treated seawater is also added potash or any other product capable of reducing excess acidity and of constituting a useful component for fertilization of plants. 4) - Apparatus for implementing the method according to one of claims 1 to 3, characterized in that it comprises - a tubular enclosure (1) for treatment at the two ends of which are respectively connected a supply pipe sea water to be treated and a pipe for discharging the fertilization liquid obtained after treatment - in the inlet end of this tubular enclosure, a nozzle (4) for injecting the acid (s) (sulfuric acid, phosphoric acid, nitric acid) to be added to the treated seawater - a helical stator (6) arranged inside the tubular treatment enclosure (1) and arranged near the inlet thereof for impart, to the seawater to be treated, a vortex movement during its circulation inside this enclosure. 5) - Apparatus according to claim 4, characterized in that at an intermediate point of the length of the tubular enclosure (1) for treating seawater, opens an injection nozzle (7) capable of injecting also ammonia in the sea water circulating inside this enclosure.  60) - Apparatus for implementing the method according to one of claims 1 to 3, characterized in that it comprises  - A bundle of a series of treatment tubes (25) arranged side by side to form a multichannel system at the two ends of which are connected respectively a pipe ~ for supplying seawater to be treated and a discharge pipe fertilizer liquid obtained after treatment;  - in the inlet end of each of these tubes (25), a nozzle (30) for injecting the acid (s) (sulfuric acid, phosphoric acid, nitric acid) to be added to the treated seawater  - inside the inlet of each of the treatment tubes, a helical stator capable of imparting a vortex movement to seawater during its circulation in each of these tubes;  7 ") - Apparatus according to claim 6, characterized in that at an intermediate point of the length of each of the tubes of the bundle of treatment tubes (25) of this apparatus, opens an injection nozzle 13-1) suitable also inject ammonia into the seawater circulating inside each of these tubes.  8) - Installation for implementing the method according to one of claims 1 to 3, characterized in that it comprises three treatment chambers (la, lb, lc) according to claim 4, connected in parallel, the inputs of which are connected to a natural seawater tank and inside each of which is injected one of the three acids provided (sulfuric acid, phosphoric acid, nitric acid), the outputs of these three enclosures being connected to a single pipe d evacuation leading to a tank inside which the fertilizing solution thus obtained is collected.  9) - Installation for implementing the method according to one of claims 1 to 3, characterized in that it comprises three treatment chambers (24a, 24b, 24c) according to claim 6, connected in parallel, the inputs of which are connected to a natural seawater tank and inside each of which is injected one of the three acids provided (sulfuric acid, phosphoric acid, nitric acid), the outputs of these three enclosures being connected to a single pipe evacuation leading to a tank inside which is collected the fertilizing solution thus obtained.  10) - Installation for implementing the method according to one of claims 1 to 3, characterized in that it comprises three treatment enclosures according to claim 4 or according to claim 6, which are connected in series as a result a natural seawater supply pipe, the quantities of acids (sulfuric acid, phosphoric acid, nitric acid) injected into these enclosures being determined to cause only partial reactions in each enclosure so that the fertilizing solution thus obtained contains both sulfates, phosphates and nitrates