FR2771654A1 - MULTI-FUNCTION METHOD AND APPARATUS FOR THE MAINTENANCE OF METASTABLE LIQUIDS - Google Patents

Abstract

The invention concerns a method for maintaining metastable liquids contained in tanks, both for curative action on layers of sediments already formed and for preventive use for eliminating cause and effects. The invention is characterised in that the metastable product contained in a tank is sucked at a predetermined level of the volume of said product liquid phase, using a suction tube (1) connected to a pump (6) suction (01), and immediately re-injected under pressure into said volume of product contained in said tank using the same pump and injection nozzles (7) connected to the pump discharge (02) via an injection tube (2) arranged, preferably concentric, in said suction tube (1).

Description

Method and apparatus with multiple functions for the maintenance of metastable liquids.

 The present invention relates to a process and apparatus with multiple functions for the maintenance of metastable liquids. The action of these processes and apparatus can be curative (elimination of the layers of sediment already formed), or preventive (prevent the formation of such layers). .

 The term "metastable" denotes a property characteristic of certain liquid phases, the physico-chemical stability of which is subject to modifications. Example: segregation or sedimentation due to gravity and / or temperature.

 Fields of application of the invention.

 The stored metastable liquids and their deposits have particular physicochemical characteristics, with segregation effects that are difficult to avoid.

 We know that the heaviest of the elements they contain, gradually deposit, during their operation, accumulating on the bottom and sometimes on the walls of the tanks.

 This physicochemical phenomenon and its consequences on the smooth running of industrial operations, is still currently the cause of costs, of losses, direct or induced, and sometimes also, of human and ecological material nuisances.

These sediments depend on various factors with regard to their abundance or their composition. We will quote for example:
The very nature of the product stored and, more particularly, the
differences in molecular weight of its various components.

. Climatic conditions and temperature variations.

The frequency of filling and emptying movements in the
tank considered during its period of service.

 The above-mentioned indications are in no way limiting.

 Once the sedimentation process has started, in the form, at its beginning, of a simple thickening of the lower layers of the stored liquid, it will become accentuated over time; the sediment which forms becomes more and more compact, in some cases including molecular bonds forming strata. It hinders the operation of the reservoir and its contents, it reduces the available capacity.

Examples of applications:
Storage in tanks of compound chemicals, hydrocarbons, petrochemicals and liquid raw materials.

 Storage in industrial waste tanks or lagoons awaiting treatment.

 We also think of particular operations due to the dimensions or the environment: curative operations which have become essential due to accumulation under penalty of stopping operation, for example concerning large reservoirs, equipping drilling platforms and offshore extraction, we also think of underground storage and storage on board disused tankers, we think of the countless lagoons containing discharges practiced awaiting technical, ecological and economic solutions.

Aim
The present invention proposes to remedy the problems of segregation or homogeneity posed, during their storage in reservoirs, by certain liquid phases comprising elements of different molecular weights or natures.

 These deposits have consistencies ranging from that of a soft mud to that of a compact mass evolving, eventually, towards their solidification.

 These deposits have been considered over the past decades as the repercussions, annoying, but more or less inevitable of the industrial processes at their origin.

 Their harmfulness to the environment, to public health and, above all, to that of the men employed in their extraction has only recently been assessed and taken into consideration.

 Their future has generally only been planned recently, and is still a problem. It was often simpler and above all less expensive to reject, abandon or even bury these troublesome residues once extracted, rather than subject them to inevitably expensive treatments.

 Their possible re-use or revaluation has long been considered secondary due, on the one hand, to the lower cost of the raw materials that generated them, on the other hand, by a lack of ecological awareness due to the economic imperatives of a industry subject to financial results. This home, is currently well aware of the importance of preserving the living environment, a motivation to which are added the increased costs of waste and raw material treatments, putting an end to the illusion of savings, term, fallacious.

 Air emissions caused by operations to extract these sediments, carried out under forced ventilation (for the protection of men used for manual or semi-manual tasks in unsanitary or even dangerous environments) are certainly invisible for the most part, but this however, there are considerable volumes on a global scale which are thus issued without control or treatment, which have only recently been evaluated and taken into account.

Most of these sediment deposition extractions are still carried out worldwide. They are as unsanitary and sometimes dangerous for men at work as for
The environment.

 An object of the invention is to make available to industry a relatively simple means in its application and, ultimately, less costly from all points of view than an unnecessary squandering of raw materials becoming economically valuable, while preserving human health and their natural heritage.

On the other hand, the invention proposes to use a multifunction apparatus having the following operating characteristics:
To be able to be used under the various types proposed as well for a curative action on layers of sediments already formed, as for a preventive implementation, suppressing both the cause and its effects, the same apparatus being able moreover, to be used for ensure the final decontamination of the treated capacities.

Can be either mounted quickly and almost autonomously for occasional interventions, or permanently installed and activated at the intervals and frequencies defined by the operator.
avoid modifications to the existing tank or its piping.

 Authorize the continued operation of the tank during preventive operations or corrective use, without significant interruption of service.

 Use energy specific to the system, or available on site; and which is quick to set up and implement.

 Be able to be used in liquids of different natures while meeting the safety obligations for products subject to specific regulations because of their characteristics, their corrosivity, their fumes or their toxicity.

 Ensure optimum safety conditions in tanks containing flammable products or gases.

 Ensure maximum environmental protection, excluding any atmospheric or terrestrial release caused by its implementation.

 Exempt the labor force from any contact with the sediment and the liquid from which it comes or with its emanations.

Allow (if the nature of the product and the composition of the sediment make it possible or desirable) a reuse of the usable components of the sediment, made homogeneous, suitable for upgrading.
avoid costly curative maintenance operations for the operator, in the event of preventive use of the invention.
between, in case of preventive use, of a moderate operational cost, comparable to those current in industrial installations.
between modular with regard to their basic functions: flow rates, pressure, rotation, etc.

State of the art
Certain deposits, because of their inert nature and the technique used, as well as their consistency, have long been the subject of well known treatments (injection of liquid under pressure, compressed air, stirring, etc.) to facilitate their extraction. They do not fall within the framework provided for the applications of the invention.

 In order to remedy the drawbacks caused by the storage of liquid phases which have caused physico-chemically non-inert deposits, the operator has these deposits, the consistency of which, according to his own needs or technical contractual and regulatory obligations generally limits efficient pumping or transfer.

 Various means or procedures are used or proposed for this extraction, they are, in general, specific to the stored product and the deposits it has formed, which can, in certain cases, be reusable or revalorizable.

 These means are most often manual or semi-manual.

Certain deposits make the work of men painful, unhealthy or dangerous, these methods do not always ensure that the extracted sediments become fate protecting the environment and may require costly additional treatments (exteriorization, transport, incineration, centrifugation ...).

 Hydrodynamic processes currently used for the curative treatment of certain deposits (these are "corrective" procedures) having the following drawbacks: they intervene on deposits already formed and more or less stabilized. They require the stopping or a significant slowing down of the exploitation of capacities or tanks, transfers, the use of often heavy equipment, to which must be added assembly and disassembly operations of pipes, conduits, cables, driving relatively long lead time at high cost.

 These high costs and wasted time limit the use of such procedures to corrective operations which have become essential. Because of the costs and the complication of their implementation, such methods cannot constitute a solution which makes it possible either to remedy the drawbacks of existing sedimentation but to prevent its formation, the only solution making it possible to eliminate the discomfort and the losses caused by this phenomenon.

 Current procedures and their equipment are "rigid" in their use. There is no question of seeing them used to achieve the best valid goal in this area: the prevention of the formation of these sedimented deposits, both for operational reasons and for economic reasons.

Statement of the invention
The method of the invention is particularly remarkable in that the metastable product contained in a reservoir is aspirated to a determined level of the volume of the liquid phase of said product, by means of a suction tube connected to the suction of a pump, and immediately reinjected under pressure into a layer of the product contained in said reservoir, by means of this same pump and injection nozzles connected to the discharge of the latter via an injection tube housed in said suction tube.

 The apparatus according to the invention is remarkable in that it comprises at least one module comprising two concentric tubes, ie a first tube of larger section (outer tube) comprising in its lower portion, at least one and, preferably, a plurality of suction ports and the upper portion of which is connected to the suction port of a pump, and a second conduit (inner conduit) the upper portion of which is connected to the discharge port of said pump and the lower end of which is connected to injection nozzles, preferably rotary.

ADVANTAGES OF THE INVENTION
The method and the apparatus according to the invention meet the various objectives mentioned above.

 On the other hand, the invention proposes to meet these objectives by the use of autonomous modules, the particularity of which is to carry out, in a single device, the functions of suction of the liquid contained in the reservoir and of its discharge under pressure in this, within which flows will be directed and distributed throughout the volume contained in the tank, these flows being adapted to the goals to be achieved depending on the nature of the operation: resuspension, fluxing, liquefaction - pumpability, homogenization, washing, decontamination.

 In addition, the "multifunctional" nature of the claimed apparatus makes it possible to have in the same apparatus, as well an attack power essential to the dispersion in the contained volume of the most compact sediments and / or the most agglutinating; and an essential complementary successive stirring, of the same volume, with a view to its homogenization, if this is the aim sought.

 The module according to the invention has multiple functions since it allows, by providing for it before installation, the specific adaptations to the operation, to distribute flows suitable either for specific corrective operations or for preventive implementation. This constitutes a considerable advantage, both for the service responsible for the works, inside an industrial installation, and for a contractor mandated by the industrialist.

 The energy necessary for the functions of the modules: suction, pressurization, delivery, rotations, can be provided either by a hydraulic group, or by a pneumatic group, or electrically.

Without excluding these latter possibilities, a set of equipment driven by hydraulic pressure will be described below according to a preferred embodiment. This will avoid the standard problems and constraints associated with the use of electricity in certain installations or certain sensitive liquids as well as those possibly caused by the use of compressed air.

 Each module is autonomous in the sense that it can be mounted directly on the available opening (s), in the roof or the side wall of the tanks, via a base or a suitable cover to the dimensions of these. The number of modules and their dimensions are a function both of the liquid and of the deposit to be treated and of the geometry of the reservoir itself. No other assembly is necessary, only the hydraulic supply piping and its connection to the hydraulic groups or power stations located either on the ground, outside the tanks, or at any other location chosen according to the site, being then necessary.

BRIEF DESCRIPTION OF THE DRAWINGS
The aims, characteristics and advantages above, and still more, will emerge more clearly from the description which follows and from the appended drawings in which:
Figure 1 is a front view, in axial section and in schematic nature, of a suction and injection module according to the invention.

 Figure 2 is a view similar to Figure 1 showing an alternative embodiment of a suction and injection module according to the invention.

 Figure 3 is a schematic front view illustrating a second alternative embodiment of a suction and injection module according to the invention.

 Figure 4 is a perspective view and schematic showing an example of implementation of the method and apparatus according to the invention in a large floating roof tank.

 Figure 5 is a perspective view in schematic illustrating an example of implementation of this method and this apparatus in a fixed roof tank of reduced dimensions.

 Figure 6 is a vertical sectional view and schematic showing the implementation of the method and the apparatus claimed, in a pit (or basins, or lagoon).

 Description of an example of implementation of the invention.

 Reference is made to the appended drawings to describe interesting examples, although in no way limitative, of implementations of the method and of embodiments of the apparatus with multiple functions for the maintenance of metastable liquids, according to the invention.

As indicated above, according to the method of the invention,
The suction of the liquid product contained in the reservoir, its pressurization and the injection of this flow within the volume contained in the reservoir, are carried out from a single and same assembly, which can be placed directly on the (or) existing orifice (s) of the tank in question.

 The apparatus according to the invention comprises at least one suction-injection module M and, preferably, a plurality of autonomous M modules whose number and dimensions are, for example, dependent on both the liquid and the deposit to be process and the capacity and geometry of the tank containing these liquid and deposit, as indicated above.

 Each module comprises two tubes 1 and 2, arranged coaxially.

 In view of the fact that these tubes are most often called upon to be used vertically, the words "lower" and "upper" will conventionally be used below to distinguish their opposite ends or end portions.

 Likewise, it is emphasized that the word "tank" used in the following description designates both a tank of variable dimensions and capacities (for example up to 130,000 tonnes or more) covered by a fixed or floating roof, as well as open air basins of different types (lagoons, lakes, etc.).

 The outer tube 1 or suction tube has a passage or conduit 3 of greater annular section than the circular section of the conduit 4 defined by the interior tube or delivery tube 2.

 The suction tube 1 comprises, in its lower portion, at least one and, preferably, a plurality of openings or stepped openings 5 distributed, preferably regularly, in its side wall.

These openings can advantageously be provided with a strainer (not shown) opposing the entry of sediments detached by the impact of the pressurized flows, and which wander within the volume of the liquid product contained in the reservoir, before being brewed and made homogeneous.

 The assembly consisting of the two aforementioned tubes is intended to be positioned vertically in the tank containing the product to be treated, so that a more or less significant part of its length is immersed in said product.

 The length of the suction tube 1 is sufficient to ensure a regular and constant suction by its section or its orifice immersed in the liquid contained in the tank and / or through lights made at the height of the chosen liquid phase.

 The length of the delivery tube 2 depends on the nature of the operation to be performed, said tube being either interchangeable in its lower sections, or telescopic, or extendable. For example, in the case of a corrective operation, the length of the delivery tube will be determined by the level of the sedimentary layer to be treated already formed, its nature and its consistency, in order to penetrate and disintegrate this sedimentary phase.

 As shown, for example, in FIG. 3, the suction tube 1 can be made up of several sections 1 a, I b assembled by means of threaded connections In. The same applies for the delivery tube 2 and for tree 9.

 The upper end of the outer tube 1 is connected to the suction orifice 01 of a pump 6, the casing or body of which can be rigidly attached to the upper part of the assembly constituted by the tubes 1 and 2, said pump can be placed axially or laterally with respect to said assembly. A filter 20 is placed in front of the suction port 01 of the pump 6.

 On the other hand, the upper end of the inner tube is connected to the discharge orifice 02 of the pump 6.

Pump 6 will be chosen according to:
- its construction, compatible with the products to be treated;
- its good suction power; it will be self-priming;
- its efficient flow-pressure couple.

 This pump thus ensures suction, pressurization (for example under a pressure of the order of 5 to 25 bars) and injection of a flow which will be put into permanent circulation throughout the duration of the operation, until the goals set for liquefaction, fluxing and / or homogeneous resuspension of the sediment elements have been achieved.

 According to the example illustrated, the pump 6 is driven by hydraulic energy, the generator and the supply of hydraulic energy being installed on the ground or on any other location chosen according to the industrial site, outside the tank containing the product. treat. The power of this hydraulic energy depends on the number of modules used for the treatment considered and it is adapted to the volume and to the nature of the liquid or of the sediment to be treated. Of course, any other type of energy chosen by the operator for reasons of local operation could be used for the operation of the pump 6.

 The lower end of the delivery tube is connected to hydrodynamic injection nozzles 7, preferably rotary.

 The rotary drive of these rotating nozzles can be ensured by means of a hydraulic motor or turbine 8. Any other energy can however be substituted for hydraulic energy, at the discretion of the operator, without this in any way modifying the principle and procedure for applying the invention.

 According to the embodiment shown (Figure 1), the motor 8 drives a shaft 9 housed in the discharge tube 2, which it crosses from one end to the other. The shaft 9 opens into a rotating casing 10 to which it is rigidly connected, this casing 10 being, for example, arranged in the extension of the lower end of the suction tube to which it is advantageously connected by means of a connector turning 11.

 The rotary nozzles 7 are arranged laterally on the casing 10, so that the rotational drive of the latter causes a circular movement of said nozzles around the vertical axis of the module (arrow F1). The rotation of the nozzles 7 around the longitudinal axis of the module takes place at a slow speed (for example of the order of 0.5 to 10 rpm), depending on the nature of the product treated and the operational phase in progress), the motor or turbine 8 being connected to the shaft 9 via a reduction gear (not shown).

 On the other hand, the lower end of the delivery tube 2 is provided with a fixed bevel gear 12 engaged with a bevel gear 13 integral in rotation with an adjustable satellite gear 14 itself meshing with a gear 15. This pinion 15 is wedged on the end of a small conduit 16 oriented perpendicular to the axis of the injection tube 2. This conduit 16 is mounted rotating in a bearing 17 which is provided, laterally, the casing 10 and the nozzles 7 are mounted on the distal end of this conduit which is outside said casing. In this way, the nozzles 7 are also mounted rotating in planes parallel to the injection tube (arrow F2), at a speed which is also a function of the nature of the product treated and of the operational phase in progress, for example at a speed between 0.5 and 10 rpm. In other words, according to the embodiment described above, the nozzles 7 are mounted at the lower end of the module, with an aptitude for rotation in two perpendicular planes.

 The number and the flow rate of the nozzles 7 as well as the level at which they are placed in the tank, are determined as a function of the nature, the volume and the viscosity of the product to be treated, as well as the technical lessons obtained by sampling and analyzes indicating, prior to the implementation of the process and the system, the areas planned for the intervention.

The minimum length of the range of hydrodynamic jets spouting from nozzles must obey the following rules:
- all the areas to be treated must be flowed by the impact of the jet; no zone must remain excluded from mixing;
- consequently, as a function of the hydronynamic impact radius obtained, the number of modules to be used for large tanks and / or high viscosities of the products to be treated will be multiplied, so as to obtain an overlap of the radii d 'actions between them.

 The nozzles are advantageously mounted on the nozzle threads arranged at the outlet of the duct 16, these threads being able to receive nozzles of given section, geometry and orientation.

If the number of available nozzles is not fully used, unused nozzles can be sealed with threaded plugs.

 All the basic characteristics of the module: flow, pressure, rotation,. ., are modular and adjustable according to the observations, studies and analyzes carried out prior to the treatment operation and, if necessary, during it.

 The positioning structures of the modules for their implementation can be very different depending on the configuration of the tanks containing the products to be treated.

For example:
for the treatment of the products contained in reservoirs R 'with fixed roof T2, the module or modules M (FIG. 5) can pass through openings generally provided in the original in said roof and be supported by the latter; in this case, the length of the modules is adapted to the height of the tanks; they can possibly rest on the bottom of the tanks, so as to ensure their rigidity, by resting either on rotating bases, or on small fixed bases 18 (FIG. 2) equipped with sealed bearings allowing the rotation of the rotary nozzle holder 10;
for the treatment of products contained in tanks R with a floating roof T1, the modules M (FIG. 4), can be mounted in a similar way, by resting on the bottom of said tanks; in this case, the dimensions and specifications of the tube 2 and, above all, of the outer tube 1, are determined so as to ensure the same resistance to stresses as the crutches equipping the original floating roofs; these tubes are therefore capable of supporting these floating roofs, when the tank has been emptied of its contents;
for the treatment of the products contained in open ponds B (lagoon installations), the modules M (figure 6) can be fixedly installed on walkways or on trolleys moving on these.

The upper part of the external element (tube 1) of the module can be arranged to allow adjustment of the position thereof in the axial direction, that is to say, therefore, adjustment of the position, in height, suction lights (5) and the rotary nozzle holder 10. For example, the vertical external element 1 of the module can be provided, laterally, in its upper part, with a rack 19 called upon to cooperate with a device for lock (not shown) fitted
The entry of the passage P formed in the roof T of the tank for the engagement of said module.

 As indicated previously, the module can have an adjustable length; in this case, its longitudinal components (suction tube 1, injection tube 2, shaft 9) can be made up of sections assembled by means of suitable screw connections.

 The module according to the invention can also be used in a horizontal position. In this case, it is engaged horizontally in one of the manholes provided at the base of the side wall of the tanks.

 Obviously, all accessories, parts, etc ... comply with the standards and technical and safety obligations applying to the nature of the contents of the tank and the site in which the operation is planned.

Examples:
First, intrinsic safety, the risks of static electricity are made impossible; by the equipotentiality of the "earthed" system.

 Second, the fact that fluxes take place only immersed, excludes any other creation of static electricity.

 The regular distribution of the flows in circulation, their dispersion, their orientation are ensured, in the event of preventive operation, by the thrust of the hydrodynamic jets submerged inside the volume contained in the tank.

 The duration of the processing operations is determined by the probes

 It is the same for the frequency of interventions, which can only be determined by the observations of the tank operator.

At the extreme limit, in certain cases, provision may be made, permanent or sequential, for the intervention, carried out by all or part of the modules according to the results observed.

 The implementation, during preventive interventions preferably includes the permanent installation of the modules on the reservoirs provided. The modules are then protected by a rigid cover, sheltering them from the weather, from installation and removal requiring no special handling.

 Putting them into action will only require connection to the hydraulic groups of the supply and distribution hoses, the distribution manifolds also remaining at a fixed station. If the unit is permanently installed, its order can be programmed, computerized and carried out remotely from a centralizing station.

 In the case of corrective operations, one of these may be only the first phase of an intervention plan, intended first of all to eliminate and / or recover the sediments already formed, then, in a second phase, using the same system, after having possibly adjusted it to the specific needs of a preventive intervention: level and number of nozzles, their section and geometry, number of modules, flow rates, pressures, etc. ..., in particular for large oil tanks.

We have previously insisted on the multifunctional nature of the invention. There are two fundamental ones which, in the case of a curative operation, are both different and, without exception, inseparable:
Dislocation in the literal sense of the term sediment is indeed an essential prerequisite as soon as deposits have a compact character; a result that simple mixing turbulence cannot achieve effectively.

 Mixing, just as essential, as soon as the deposits have been dislodged, detached from the bottom or walls of the tank to which they frequently adhere.

These additional functions will be satisfied by the adaptability of the module:
If, in the case of preventive action, the flow put into circulation by the module represents the main parameter, more important than the pressure under which it is dispersed in the volume in which the formation of sedimentation must be prevented, these factors are almost reversed when it is a corrective intervention, on a formed, adherent and compact deposit.

 In the first case, the only hydrodynamic energy organized by the nozzles with which the delivery tubes are provided is sufficient to disturb and keep in motion the volume contained in the tank.

 During a curative intervention, this hydrodynamic energy remains the "engine" of the system but, in addition to the flows injected by the nozzles into the volume contained in the reservoir, the delivery tube can, and sometimes, must be provided at its part. lower, more aggressive elements in the form of arms 21 (FIG. 3) mounted with a tilting ability in vertical planes, these arms extending the range of these submerged jets increasing both their range of action and the impact caused by the extension of submerged turbulence. The arms 21, the free end of which is provided with an injection nozzle, are mounted with an aptitude for rotation about the axis of the delivery tube 2 at the lower end of which they are connected.

 When this is made possible by the nature of the liquid contained in the reservoir and by that of the sediments, by the dimensions of the reservoir, an attempt will be made to combine the two functions of dislocation and mixing, in the same module. Thus, the injection tube, in its lower part, will dislocate the sediment by means of its arms 21; then (in its middle and upper part) will brew it through the nozzles.

Its rotational movement will ensure that the entire volume contained in the tank is set in motion.

The process according to the invention would not be complete if it did not return to their operator, reservoirs whose state of the interior surfaces (bottom, walls, structures) authorize, according to his needs and at his choice:
- the penetration of labor and inspection personnel into an atmosphere devoid of harmfulness, breathable without mask or protective device;
- necessary maintenance work, including flame repair work.
classification of the tank, if it is intended to receive subsequently, other products.

 When the treatment requires rinsing, a rinsing liquid is chosen according to the nature of the deposit from which the tank must be rid. In this case, the suction port will be opened at the lowest level so as to save the amount of rinse aid.

 Washing of the internal surfaces is then carried out in accordance with the operation described in the preceding titles. After stirring and controls, the washing liquid is pumped out of the tank to be either recovered, treated or eliminated by any method suited to its nature (purification station, neutralization, centrifugation, filtering, etc.).

 Such a washing can be renewed, if necessary, and the rinsing liquid modified according to the results observed until obtaining the desired cleanliness and the elimination of any dangerous, harmful or explosive internal atmosphere.

 In the case of liquid, the gaseous fumes of which can be explosive or toxic, the washing method will be forced to submerged stirring, ie a level of liquid appreciably higher than the rotary jets.

 In the case of products which do not present these risks, it is possible to proceed by direct projections of the rotary jets onto the internal walls of the tank.

 Choice of liquid: it will depend on the results objectives (technical, economic and ecological performance) but it must always comply with the regulations and safety instructions.

 Notwithstanding the possibility of manual finishing (the penetration of men having become possible thanks to the previous phases), it will be possible to multiply the washing phases and the products used, until the required degree of cleanliness is obtained.

 It is therefore the same modules and their specific operating mode, which ensure the extraction of the sediment made pumpable, then the cleanings, without requiring installation or additional assemblies.

Claims (17)

 CLAIMS 1. - Method for the maintenance of metastable liquids contained in reservoirs, both for a curative action on layers of sediment already formed, and for a preventive implementation, eliminating both the cause and its effects, characterized in that the metastable product contained in a reservoir is sucked at a determined level of the volume of the liquid phase of said product, by means of a suction tube (1) connected to the suction (01) of a pump (6 ), and immediately reinjected under pressure into said volume of product contained in said reservoir by means of this same pump and injection nozzles (7) connected to the discharge (02) of the latter via a tube d injection (2) housed, preferably concentrically, in said suction tube (1). 2. - Method for the maintenance of metastable liquids contained in reservoirs, according to claim 1, characterized in that the injection nozzles (7) are driven in a rotational movement (F1) around the axis of the tubes concentric suction (1) and injection (2). 3. - Method for the maintenance of metastable liquids contained in tanks, according to one of claims 1 or 2, characterized in that the injection nozzles (7) are driven by a rotational movement (F2) in a plane parallel to the axis of the concentric suction (1) and injection (2) tubes.  4. - Method for the maintenance of metastable liquids contained in tanks according to claim 2, characterized in that the injection nozzles (7) are mounted at the end of the arms (21) which it is possible to pivot in vertical planes. 5. - Method for the maintenance of metastable liquids contained in reservoirs, according to any one of claims 2 to 4, characterized in that the injection nozzles (7) are driven in a rotational movement (F2) in planes parallel to the axis of the concentric suction (1) and injection (2) tubes. 6. - Apparatus with multiple functions for the maintenance of metastable liquids, as well for a curative action on layers of sediments already formed, as for a preventive implementation, eliminating both the cause and its effects, this apparatus comprising at at least one module (M), characterized in that this module comprises two concentric tubes, ie a first external tube (1) comprising, in its lower portion, at least one suction port (5) and the upper portion of which is connected to the suction port (01) of a pump (6), and, a second tube (2) whose upper portion is connected to the discharge port (02) of said pump and whose lower end is connected to injection nozzles (7). 7. - Module according to claim 6, characterized in that a filter (20) is placed in front of the suction orifice (01) of the pump (6).  8. - Module with multiple functions for the maintenance of metastable liquids, according to claim 6, characterized in that the injection nozzles (7) are mounted with a rotational ability in a plane perpendicular to the axis of the concentric tubes ( 1, 2) and coupled to a motor (8) ensuring their rotation drive. 9. - Module with multiple functions for the maintenance of metastable liquids, according to one of claims 6 and 8, characterized in that the injection nozzles (7) are mounted with a rotational ability in planes parallel to the axis of the concentric tubes (1, 2) and coupled to a motor (8) ensuring their drive in rotation. 10. - Module with multiple functions for the maintenance of metastable liquids, according to one of claims 6 or 8, characterized in that the injection nozzles (7) are mounted at the free end of the arm (21) pivoting in vertical planes. 11. - Multi-function module for the maintenance of metastable liquids, according to any one of claims 6 to 10, characterized in that the external suction tube (1) comprises, in its lower portion, a plurality of stepped lights (7) formed in its side wall. 12 - Multi-function module for the maintenance of metastable liquids, according to one of claims 6 or 11, characterized in that the suction light (7), or all the suction lights (7), is fitted with a strainer. 13. - Module with multiple functions for the maintenance of metastable liquids, according to any one of claims 6 to 12, characterized in that its lower end is equipped with a base (18) for supporting the ground, disposed at < the bottom of the rotary nozzle holder (10) and connected to it by means of a bearing. 14. - Multi-function module for the maintenance of metastable liquids, according to one of claims 8, 9 or 10, characterized in that the rotary nozzles (7) are coupled to the motor (8) via a reducer. 15. - Module with multiple functions for the maintenance of metastable liquids, according to any one of claims 6 to 14, characterized in that its length is adjustable, the outer tube (1), the inner tube (2) and the shaft (9) being, for example, made up of sections (la, lob, ...) assembled by means of screw connections (ion). 16. - Apparatus with multiple functions for the maintenance of metastable liquids comprising at least one module (M) according to any one of claims 6 to 14, intended to be positioned in an opening (P) formed in the roof (T) of reservoirs, or in any other support, characterized in that the upper portion of the external element (1) of the module (M) and the inlet of said opening, are arranged in a complementary manner to allow adjustment of the position of said module , in the axial direction. 17. - Apparatus with multiple functions for the maintenance of metastable liquids, according to claim 16, characterized in that the vertical external element (1) of the module (M) or of each module (M) is provided, laterally, with a rack (19) called to cooperate with a locking device equipping the entry of the passage (P) or of each passage (P) formed in the roof (T, Ti, T2) of the tank.