FR2999950A1 - DEVICE AND METHOD FOR EVAPORATING A LIQUID AND THEIR APPLICATIONS - Google Patents

Abstract

The device for evaporating a liquid comprises an evaporation chamber (10) intended to contain a liquid to be evaporated and supply means (12) for introducing a gas into a liquid (11) to be evaporated. in the evaporation chamber (10), so as to form gas bubbles in the liquid and promote the evaporation of the liquid. The evaporation device can be implemented in an installation for the production of electrical energy by evaporation / condensation of seawater.

Description

TECHNICAL FIELD The present invention relates to a novel device and a novel process for evaporating a liquid. BACKGROUND OF THE INVENTION The invention finds its application in all areas where it is necessary to evaporate a liquid, including water. The invention preferably, but not exclusively, its application to the production of electrical energy from water vapor, especially from the evaporation of water pumped in a natural environment such as in particular seawater , water from a lake, or water from a watercourse, or groundwater. The invention is also applicable to the distillation of a liquid by evaporation / condensation, for example to desalt seawater, or purify a liquid. The invention also finds application in the field of heat pumps or in the field of industrial cooling, in particular industrial cooling of a liquid, or a gas, air conditioning, refrigeration. Prior art At normal atmospheric pressure (at sea level) evaporation of water occurs around 100 ° C. This evaporation occurs when the external environment supplies energy to the water that has become vapor in the form of latent heat L. As long as the water remains in its vapor state, this energy Lv remains stored in this vapor. If we reduce the temperature of the vapor, we then witness the phenomenon of condensation by which the vapor is transformed into liquid by yielding this stored energy to the outside environment. We often speak of evaporation and boiling without distinction for the passage from the liquid state to the gaseous state. In reality, these two phenomena are different and appear in different circumstances. Evaporation refers to the appearance of molecules in the gaseous state at the surface of the liquid. If we bring energy quickly to the bottom of a container, the temperature rises gradually over the entire water column, but at the level of the surface in contact with the energy supply, the temperature will quickly exceed the evaporation temperature (100 ° C for water at normal atmospheric pressure). This creates local evaporation in the form of small bubbles in the water that will escape and rise into the liquid due to buoyancy. This phenomenon will accelerate with the rise of the temperature of the liquid and the number of bubbles becomes important; we then obtain the so-called boiling phenomenon. It can be said that boiling is a three-dimensional or volume evaporation in contrast to conventional surface evaporation. The evaporation of a liquid, and in particular of water at low pressure, is also a well known and controlled method. This evaporation method is related to the fact that the evaporation temperature of a liquid, and in particular of water, decreases with the atmospheric pressure above this liquid. For example at 0.2 bar, the evaporation temperature of the water is of the order of 60 ° C; at 20 mbar, the evaporation temperature of the water is of the order of 17.5 ° C. Thus, if, for example, water at 20 ° C. is placed in a container, such as for example a beaker, nothing happens in the short term at atmospheric pressure. If the container is placed in a vacuum bell connected to a vacuum pump, the water boils suddenly, and the temperature of the water decreases more and more, to finish at a temperature below zero. From a certain moment, the remaining water eventually freezes, putting an end to evaporation. It is therefore possible by lowering the pressure sufficiently to evaporate and boil water at low temperature, for example at 20 ° C. When a liquid such as water evaporates, it needs energy to pass from the liquid phase to the gas phase: it is the latent heat L. The latent heat Lv is equal to 2.25 MJ / kg for water at atmospheric pressure. This energy is provided by the volume of the water in the liquid state that does not evaporate and by the container containing the water in the liquid state, which provide this thermal energy by lowering their temperatures. As long as evaporation continues, the temperature continues to drop to below 0 ° C and the liquid water eventually turns to ice. If we neglect the participation of the container, we can consider as a first approximation, that there conservation energy between the energy received by the evaporated water and the energy provided by the liquid water. Eeva = Eliq where Eeva is the energy received by the evaporated water and Eliq is the energy supplied by the liquid water. Elig = mliq Coq AT where, mliq is the mass of non-evaporated liquid, Cpliq is the heat capacity of the liquid and is worth 4.6kJ / kg / K for the water and AT is the variation of the temperature of the liquid water. Where Meva is the mass of evaporated liquid and Lv is the latent heat and is 2.25 MJ / kg for water at atmospheric pressure. The conservation of the energy and the matter requires that Eeva = Eliq therefore Meva 1-v = rniiq Coq AT It is this relation (Eeva = Eliq) which makes it possible to extract energy of a liquid by evaporation, and for example extracting energy by evaporation of water pumped in a natural environment such as in particular seawater, lake water or water from a watercourse. This phenomenon of evaporation of a liquid, and in particular of water, at low pressure, has been used for many years to produce steam and to use the steam produced to generate electrical energy. This electrical energy produced from water vapor can be obtained by means of a turbine, such as for example in French patent applications FR 2 515 727 and FR 2 534 293. This electrical energy can also advantageously be 30 produced by condensation of the steam, and in particular of the water vapor produced, and by transformation into electrical energy of the energy recovered during the condensation of the steam. In particular, over the last decade, the conversion of thermal energy from oceans and seas has made significant progress with Ocean Themal Energy Conversion (OTEC) technology.

OTEC systems are described for example in international patent applications WO 81/02231, WO 95/28567 and WO 96/411079 and in US Pat. No. 3,967,449, and convert heat energy into electricity using the temperature difference. between warm sea-water on the surface and deep-sea cold water.

Usually closed cycle OTEC systems utilize a thermodynamic cycle of an intermediate working fluid. For this, there are three Rankine, Kalina and Uehara thermodynamic cycles that are compatible with the principle of OTEC systems. Rankine Cycle: This cycle is used with organic liquids that have a boiling point lower than that of water. Therefore, it is called Organic Rankine Cycle (ORC). Kalina cycle: http: //www.thermoptim. This cycle uses a mixture of water and ammonia as the working fluid. The ammonia concentration is variable depending on the need of each stage of the cycle. In theory, the efficiency is 20% higher than that of the ORC cycle. The working fluid (water + ammonia) is boiled using the heat released by the hot source. Then, the fluid enters a separator and divides into two: - the vapor phase with a high concentration of ammonia that subsequently enters the expansion turbine that rotates the electricity generator. the liquid phase with a low concentration is used in the regenerator. Thereafter the two streams are fused in the condenser, where the fluid condenses by giving heat to the cold source. The fluid leaving the condenser and preheated in the regenerator and the same cycle starts again. The Kalina cycle is a cycle that has the particularity of varying the concentrations of the coolant (water + ammonia) to change the operating points. Indeed, at the level of the exchanger the ammonia concentration is high, which makes the evaporation temperature low. Thus the fluid can be evaporated at a lower temperature. If the concentration of ammonia is low, it makes the condensation temperature higher and it thus becomes easier to condense the vapor since the liquid that will be used to condense (cold source) will not need to be very cold. Uehara Cycle: http://www.thermoptim.org/sections/technologies/systemes/cycle-uehara This cycle also uses water and ammonia as a fixed ammonia working fluid, but its theoretical efficiency is superior to Kalina and this cycle is especially suitable for hot spring temperatures between 20 and 30 ° C. This cycle of electricity generation using the thermal energy of the seas is an improvement of the Kalina cycle. Its main feature is to simplify the change in the composition of the water-ammonia mixture by resorting to a stepped relaxation with sampling. Just as for the Kalina cycle, the interest of this cycle is to replace evaporations and condensations at constant temperature of the working fluid by evolutions with sliding of temperature, and thus to reduce the irreversibilities of the system. In this cycle, a mixture rich in ammonia is heated in an economizer and a vaporizer, from which it comes out in the two-phase state. The vapor and liquid phases are then separated, the first being expanded to an intermediate pressure in a turbine. Part of this expanded stream is re-circulated at medium pressure, then cooled by exchange with the base mixture, to which it is mixed, to form the working fluid, which is then pressurized again.

The main stream leaving the turbine is expanded to the low pressure in a second turbine and then directed to an absorber, where it is mixed with the liquid fraction leaving the separator and previously cooled in the regenerator by exchange with the outgoing working fluid. from the rich pump, then relaxed at low pressure. At the absorber outlet, the base mixture obtained is condensed before being compressed to the intermediate pressure. In practice, a 100MW OTEC installation operating with a Uehara cycle has the following characteristics: - Net electrical power: 64MW - Daily electricity production of 1.5GWh - Annual electricity production of 514GWh - Daily freshwater production: 120000m3 / day - Hot seawater flow: 111m3 / s (= 111111kg / s) - Cold seawater flow: 111m3 / s (111111kg / s) - Electrical requirement (generally for pumps): 23MW. The major drawbacks of OTEC systems, and in particular OTEC based on the Uehara cycle, are: - very high inflow rates of hot and cold seawater and their potential effects on the environment. - the suction of water at large depth (usually 1000 meters) for the condenser, which greatly reduces the efficiency of the system. OBJECT OF THE INVENTION An object of the invention is to propose a new technical solution which makes it possible to improve the evaporation of a liquid, and in particular of water, and also to better control this evaporation. When this solution is applied to a system for converting the heat energy of the water pumped into a natural environment, it makes it possible to improve the energy conversion efficiencies and the implementation costs of the conversion system. energy.

SUMMARY OF THE INVENTION The first subject of the invention is a device for evaporation of a liquid, comprising an evaporation chamber intended to contain a liquid to be evaporated and supply means for introducing a gas into a liquid. liquid to evaporate contained in the evaporation chamber, so as to form gas bubbles in the liquid and promote the evaporation of the liquid. This forced boiling of the liquid by introducing a gas, and for example air, into the liquid to be evaporated, advantageously makes it possible to promote the evaporation of this liquid, and also makes it possible to control this evaporation, and in particular the amount of Steam produced over time, controlling the flow of gas entering the enclosure. The invention thus makes it possible to produce with low energy steam at low temperature. This low-temperature steam then advantageously requires a source which is less cold, to recover by condensation the energy stored in the steam in order to transform it into electrical energy. The energy conversion efficiencies are improved. More particularly, the evaporation device of the invention may comprise the following additional and optional features, taken in isolation, or in combination with each other: the supply means comprise a compressor, an intake manifold, a gas in the compressor and an outlet pipe for injection into the liquid to evaporate gas delivered by the compressor. The feed means make it possible to automatically regulate the supply flow rate of the gas entering the evaporation chamber. - The evaporation chamber is at atmospheric pressure. - The device comprises means for a depression of the evaporation chamber. The device comprises liquid renewal means for supplying the evaporation chamber with liquid and discharging liquid contained in the evaporation chamber. - The means (liquid renewal can supply the evaporation chamber with liquid at a temperature greater than the temperature of the liquid contained in the evaporation chamber - The liquid renewal means can supply the evaporation chamber with liquid at a temperature below the temperature of the liquid contained in the evaporation chamber - the liquid renewal means comprise in the evaporation chamber one or more evacuation openings of the liquid, preferably positioned near the bottom of the enclosure or in the bottom of the enclosure - The liquid renewal means are able to automatically regulate the flow of liquid entering the evaporation chamber. liquid renewal comprises a hydraulic pump for forced feeding of the evaporation chamber in liquid - the liquid renewal means comprise a a feed stream which is adapted to form a column of liquid, and whose upper end communicates with the evaporation chamber, and a hydraulic pump for forced supply of liquid from said supply line. - The means of liquid renewal are designed to pump water in a natural environment, including sea water, lake water or water from a watercourse, or water. 'underground water. - The injectable gas in the liquid is air or a mixture based on air. - The injectable gas in the liquid comprises helium. - The device is suitable for evaporating a volume of liquid water. - The device is adapted to evaporate a volume of liquid at an evaporation temperature below the boiling temperature of the liquid. - The device is adapted to evaporate a volume of liquid water at an evaporation temperature of less than 100 ° C, preferably less than 50 ° C, and more preferably still less than 25 ° C. - The device performs an air conditioning function: the injectable gas in the liquid is ambient air, and the device allows to evacuate into the ambient air outside the evaporation chamber cooled air from the air 'evaporation. The second subject of the invention is also an installation for treating a liquid by evaporation and condensation. This installation comprises an evaporation device referred to above, in which the upper part of the evaporation chamber intended to contain the steam communicates with a condensation system which makes it possible to condense the steam coming from the evaporation chamber. More particularly, the installation of the invention may comprise the following additional and optional features, taken alone, or in combination with each other: The installation allows the production of electrical energy; the condensation system makes it possible to condense the steam coming from the evaporation chamber and to recover the energy of this condensation by transforming it into electrical energy. The condensation system uses a Kalina cycle, or a Uehara cycle or a Rankine cycle, or a cycle derived from one or other of these cycles. The installation comprises a receptacle for the liquid resulting from the condensation of the vapor. The evaporation chamber of the evaporation device is fed with water pumped in a natural environment, and in particular sea water, lake water or water from a water course; water, or groundwater. The gas supply means make it possible to inject air into a liquid contained in the evaporation chamber by taking all or part of this air in the ambient air. - The gas supply means for recycling the gas from the evaporation chamber by re-injecting all or part of the evaporation chamber. The third subject of the invention is also a process for evaporation of a liquid during which a liquid to be evaporated is introduced into an evaporation chamber, and a gas is introduced into the liquid contained in the evaporation chamber. in order to form gas bubbles in the liquid and to promote evaporation of the liquid. More particularly, the process of the invention may comprise the following additional and optional characteristics, taken alone, or in combination with each other: The evaporation chamber is at atmospheric pressure. - The evaporation chamber is depressurized (pressure below normal atmospheric pressure). - The pressure is automatically regulated in the evaporation chamber above the liquid. - The flow of gas entering the liquid is automatically regulated. - A part of the liquid is continuously replaced in the evaporation chamber with new liquid. Continuously replacing part of the liquid in the evaporation chamber with new liquid at a temperature higher than the temperature of the liquid contained in the evaporation chamber. Continuously replacing part of the liquid in the evaporation chamber with new liquid at a temperature below the temperature of the liquid contained in the evaporation chamber. - The flow of liquid entering the evaporation chamber is automatically regulated. - The gas introduced into the liquid is air or a gaseous mixture based on air. The gas introduced into the liquid comprises helium. - A liquid volume is evaporated at an evaporation temperature below the boiling point of the liquid. - The liquid contained in the evaporation chamber is water. The water is evaporated in the evaporation chamber at an evaporation temperature of less than 100 ° C., and preferably less than 50 ° C., and more preferably less than 25 ° C. - The liquid contained in the evaporation chamber is water pumped in a natural environment and in particular sea water, lake water or water from a watercourse, or groundwater. - The liquid vapor produced is condensed in the evaporation chamber. - The condensation energy of the steam is recovered. - We recover the condensation energy of the steam and transform it into electrical energy. - We recover the liquid from the condensation of steam. - A portion of the gas injected into the liquid to be evaporated is air taken from the ambient air. - At least a portion of the gas injected into the liquid is recycled by being reinjected into the liquid to be evaporated. The gas injected into the liquid is air taken from the ambient air and the cooled air resulting from evaporation is discharged into the ambient air outside the evaporation chamber. The gas injected into the liquid is a hot gas, and this gas is cooled by evaporation of the liquid contained in the evaporation chamber. The invention also has for other objects the following uses listed of the device or the installation or the method referred to above: - Use of the aforementioned device or the aforementioned method for cooling the liquid contained in the evaporation chamber. - Use of the aforementioned device or the aforementioned method for cooling the gas injected into the liquid contained in the evaporation chamber. 30 - Use of the aforementioned device, or the abovementioned plant or the aforementioned process, for producing energy from the steam produced, and more particularly for producing electrical energy. - Use of the aforementioned device, or the aforementioned installation as a heat pump or as a heat source of a heat pump. - Use of the aforementioned device, or the aforementioned installation or the aforementioned method for treating a liquid containing a component and for separating by evaporation and condensation said component of the liquid. - Use of the aforementioned device, or the aforementioned installation or the aforementioned method for producing drinking water from salt water contained in the evaporation chamber. BRIEF DESCRIPTION OF THE FIGURES The characteristics and advantages of the invention will appear more clearly on reading the following detailed description of several particular embodiments of the invention, which particular embodiments are described by way of non-limiting examples. and non-exhaustive of the invention, and with reference to the accompanying drawings in which: - Figure 1 shows schematically an alternative embodiment of an evaporation device of the invention. FIG. 2 represents examples of operating curves of the device of FIG. 1, showing the evolution over time of the temperature of the water in the evaporation chamber for different initial volumes of water (21, 11). , 21) and with different air flows (41 / s, 61 / s, 6I / s). FIG. 3 schematically represents a first variant embodiment of an installation of the invention for the production of electricity by evaporation / condensation of sea water. FIG. 4 schematically represents a second variant embodiment. of an installation of the invention for the production of electricity by evaporation / condensation of seawater. FIG. 5 schematically represents a third variant embodiment of an installation of the invention for the production of electricity by evaporation / condensation of sea water. FIG. 6 schematically represents a fourth variant embodiment of an installation of the invention for the production of electricity by evaporation / condensation of water. Seawater. FIGS. 7 to 12 schematically represent five other examples of application of the invention. DETAILED DESCRIPTION FIGS. 1 and 2 FIG. 1 shows schematically an example of an evaporation device 1 of the invention. This device 1 comprises: - an evaporation chamber 10 containing an initial volume of liquid 11 to be evaporated, and for example a volume of water. Supply means 12 for introducing a pressurized gas, and for example air, into the liquid 11, so as to form gas bubbles 13 in the liquid. The supply means 12 comprise more particularly a compressor 121, an intake manifold 120 for supplying the compressor 121 with ambient air, and an outlet pipe 122, connected at one end to the outlet of the compressor. 121, and having its other end immersed in the liquid 11, so that the air produced by the compressor 121 is introduced into the liquid 11, near the bottom of the enclosure 10. The passage of a gas, such as air, through the liquid 11, causes forced boiling at low temperature (in this case at room temperature) which improves the efficiency of evaporation. This can be explained by the fact that the gas bubbles 13, which are forcedly created in the liquid by the gas, are charged with steam (water vapor if the liquid 11 is water), by sampling latent heat Lv to the liquid 11 and thus cooling the liquid in the chamber 10. Under the effect of the buoyancy, the bubbles 13 of the steam-laden gas rise faster and faster to burst on the surface some water. It should be noted that the gas may be simply air or any other gas, and for example and without limitation and not exhaustive, an air-based gas mixture, or an inert gas, and in particular helium.

The device of FIG. 1 was tested under the following conditions: Plastic enclosure 10 containing an initial volume of water 11 at a temperature of 19.5 ° C. for the curve with a flow rate of ai of 41 / s and 17 ° C for the other two curves with an air flow d 61 / s. - Temperature of the air jet at the outlet of the compressor 121: 17 ° C - Air jet pressure at the outlet of the compressor 121: 2 bars - Air jet flow at the outlet of the compressor 121: modifiable - Ambient temperature: 20 3 ° C Figure 2 shows the evolution over time of the water temperature in the enclosure 10 for different initial water volumes (21; 11; 21) and with different airflows (41 / s 61 / s, 61 / s). The curves of FIG. 2 show that the higher the flow rate of the gas, the higher the temperature of the liquid in the enclosure 10 drops rapidly. This drop in temperature corresponds to the evaporation of a certain quantity of liquid. By controlling the flow of gas at the entrance of the chamber, it acts on the evaporation rate of the liquid and the amount of steam produced over time. Thus, the introduction of a gas, and in particular air, into the liquid 11 contained in the evaporation chamber 10 advantageously makes it possible to create gas bubbles 13, and more particularly air bubbles, which allow the acceleration of evaporation. Figure 3 Production of Electric Power - Open Cycle FIG. 3 shows a first embodiment of an electricity production plant from the conversion of the thermal energy of the water pumped into natural environment, and in this particular example of seawater M.

This installation comprises an evaporation device 1 'by forced boiling according to the invention connected by a pipe 2 to a system 3 for producing electrical energy by condensation of the steam of sea water from the evaporation device 1 .

Evaporation device 1 'The evaporation device 1' comprises an evaporation chamber 10, which is positioned above sea level M. This enclosure 10 comprises, in the upper part, an opening 10a for the evacuation of the air and water vapor, which is connected to the pipe 2, and a bottom 100 in which is formed an opening 100a for its supply with seawater. This opening 100a is connected to a conduit 14 vertical, which plunges into the sea, and which is equipped with a hydraulic pump 15, for pumping "hot" seawater on the surface and forcing the enclosure 10 forcibly with this seawater " hot ". in another variant, the conduit 14 forming the liquid column could be inclined relative to the vertical. The enclosure 10 also comprises at its bottom 100 a water discharge opening 100b connected to an outlet pipe 16 immersed in the sea and allowing the evacuation of water from the enclosure 10. This outlet pipe 16 may be equipped with a waterfall energy recovery device 17, of the impeller type. In operation, the pump 15 makes it possible to feed the enclosure 10 with seawater at a temperature greater than the temperature of the seawater contained in the enclosure 10, and thus to provide energy thermally sufficient to maintain the volume of seawater in the enclosure at a temperature high enough that the phenomenon of evaporation does not slow down. The flow rate of the pump 15 may be fixed or may advantageously be regulated automatically, for example from a liquid level detection in the chamber 10, in order to maintain in time a minimum level of liquid in the chamber, and / or from a detection of the liquid temperature 11 in the enclosure 10 so as to maintain in time the temperature of the liquid above a minimum temperature threshold conditioning the evaporation of the liquid. In order to allow the forced boiling of the seawater in the enclosure 10, the evaporation device 1 'comprises, in a manner comparable to that previously described for the evaporation device 1 of FIG. , air supply means 12 comprising a compressor 121, an intake manifold 120 for supplying the compressor with ambient air, and an outlet pipe 122, connected at one end to the outlet of the compressor 121, and having its other end immersed in the column of liquid contained in the conduit 14, preferably substantially at sea level. The ambient air is thus continuously withdrawn at 1bar, is compressed by the compressor 121, for example at a pressure of 3bars or more, and is injected under pressure into the liquid 11. In another variant, the air inlets in the liquid may be multiple and positioned at different heights and if necessary with various inclinations, s the liquid column. It is also possible in another variant to have several lines 14, each with one or more air inlets. In order to facilitate the creation of the bubbles by better distributing the air at the outlet of the pipe 122, it is also advantageous to use the grid 123 in the pipe 14 at the outlet level of the pipe 12. Thanks to the air jet injected into the column of liquid contained in the vertical duct 14, the seawater contained in the enclosure 10 is forced to boil and evaporates by taking thermal energy from the liquid contained in the enclosure. By regulating the air flow entering the enclosure 10, the amount of steam produced over time is regulated. The water pump 15 makes it possible to regulate the temperature drop of the sea water and to regulate the flow rate of the production. It should be noted that the higher the air flow entering the chamber 10, the higher the height H of the water column. This height will be added to that produced by the water pump 15. This height H of the water column is used to recover a portion of the energy through the system 17 of energy recovery by waterfall. This makes it possible to compensate for a large part of the electrical consumption of the compressor 121 and the water pump 15. The enclosure 10 may, if necessary, but not necessarily be equipped with a vacuum pump (not shown in FIG. ), for lowering and regulating the air pressure in the chamber 10 above the liquid level 11, so as to lower the evaporation temperature of the liquid and accelerate evaporation. The water vapor that is created in the chamber 10 is driven by the air in the pipe 2 to the system 3 for producing electrical energy by condensation. In this particular example of FIG. 3, the water vapor is transported by the Venturi effect due to the change of inlet section of the pipe 2 relative to the section of the upper part of the enclosure 10. Preferably, a filter F is mounted at the inlet of the pipe 2 to prevent fouling of the installation downstream of the evaporation device 1 '.

In another variant, it is conceivable to equip the installation with at least one fan allowing forced circulation of the water vapor between the evaporation device 1 'and the system 3 for producing electrical energy by condensation. This condenser system 3 comprises a heat exchanger 30 and means 31 which allow a forced circulation of a coolant in the exchanger 30 with a recovery and conversion into electrical energy of a heat transfer fluid. part of the thermal energy of the coolant. These means 31 are for example suitable for implementing a closed thermodynamic cycle, of Kalina cycle type, Uehara cycle, Rankine cycle, or a derivative of one and / or the other of these cycles. water generated following the boiling and evaporation of seawater in the chamber 10 makes it possible to heat the heat transfer liquid (for example a mixture of water + ammonia in the case of a Kalina cycle) of the heat exchanger 30.

The seawater vapor in contact with the walls of the heat exchanger 30 transfers its energy to the coolant, and consequently the desalinated water condenses on the walls of the exchanger 30. This desalinated seawater 4 may advantageously be recovered in a receptacle 18 and discharged into a fresh water recovery circuit 18a.

The introduction of air into the evaporation chamber 10 advantageously makes it possible to generate low-temperature seawater vapor (for example at a temperature below 20 ° C.), without it being necessary to create the vacuum in the evaporation chamber 10. This low-temperature steam advantageously allows a heat transfer by condensation more efficient, and therefore allows the implementation of a source (heat transfer fluid) which is less cold, to recover by condensation the energy stored in the steam in order to transform it into electrical energy. It is therefore no longer necessary, unlike traditional OTEC systems, to pump seawater at very great depth to cool the heat exchanger, and energy conversion efficiencies are improved. The use of seawater vapor with forced boiling also reduces the need for structure and number of pumps (currently 100MW OTEC systems require pumps with a combined flow rate of 111m3 / s to pump water hot sea). In the installation of FIG. 3, the water pump 15 may in comparison have a relatively low flow rate. The invention thus makes it possible to extract thermal energy from seawater with a lower energy consumption than traditional OTEC 30 systems. The performance of the installation of the invention depends on the temperature of the seawater which is pumped on the surface by the water pump 15. The performance of the installation of the invention can be improved by increasing the temperature of the the air introduced into the liquid 11, because this hot air will yield its excess energy to the water vapor.

Figure 4- Production of electrical energy-closed cycle The installation can operate in a closed circuit as illustrated in Figure 4, by recycling, through the compressor 121, the dry air from the condenser system 3. In this figure 4 a solenoid valve EV is mounted on the intake manifold 120.

This modification makes it possible to reduce the power consumption of the compressor (s) 121. In fact, the use of a closed circuit compressor requires less energy, since the same air is used continuously for the operation of the system. One or more temperature sensors ST can be positioned within the air circulation circuit, in order to control the operating air temperature and to automatically control the air intake solenoid valve EV, if it is It is necessary to bring ambient air into the circuit to increase the temperature or to completely change the operating air.

Figure 5 - Combination of a vacuum evaporation and a forced boiling There is shown in Figure 5, an installation that combines vacuum evaporation and forced boiling. This installation comprises an air compressor 121 in a closed circuit, which makes it possible both to create an overpressure P2 downstream, and a vacuum Po. (Empty) upstream in the evaporation chamber 10. With the depression Po in the evaporation chamber 10, the seawater evaporates faster because its evaporation temperature is lowered. To prevent the bubbles under high pressure from disturbing the depression (Po) in the evaporation chamber 10, the height of the water column 30 (H1 + H2) must compensate for the excess pressure P2 downstream of the compressor 121. For example, if Po = 100mbar and P2 = 2bar, then the total length H1 ± H2 must be equal to 19m, with H2 = 9m. FIG. 6 shows another variant embodiment of an electrical energy production installation using a vacuum pump PV, which makes it possible to adjust the pressure inside the enclosure of FIG. evaporation 10; this a vacuum pump PV can serve as a priming system for evaporation and / or as a backup system for evaporation. FIGS. 7 to 11 show schematically other examples of applications of the invention. FIG. 7 shows an installation comprising an evaporation device 1 "according to the invention, the evaporation chamber 10 containing a liquid 11 and at least one component 11a mixed with the liquid or in suspension in the liquid 11 The evaporation chamber 10 is connected via a pipe 2 to an enclosure 5 for recovering by condensation of a purified condensate 5a originating from the evaporation / condensation of the liquid 11. This installation can be used, for example, for the desalination of seawater, the purification of a liquid and, for example, wastewater, the distillation of a liquid Figure 8 - Heat pump - Cooling The installation of Figure 8 is a heat pump which uses the evaporation for cooling the liquid 11 (eg water) contained in the evaporation device 1 and thereby pumping calories (Q) inside a building, and for transferring these calories to an enclosure of condensation 5 dep ortée, located outside the building, at which the calories (Q) are resituated outside by condensation. Figure 10 - Heat Pump - Heating The installation of Figure 9 is a heat pump which uses evaporation to cool the liquid 11 (eg water) contained in the evaporator 1 at outside a building, and thus pump calories (Q) outside the building, and to transfer these calories to a deported condensation chamber, located inside the building, at which the calories ( Q) are resituated by condensation inside the building.

Figure 10 - Industrial cooling The installation of Figure 10 uses an evaporation device 1 "of the invention to cool a liquid 11, and for example water, and produce a cooled gas and cold vapor The separation of gas and vapor can then be done by condensation.

This installation can be used for example for the industrial cooling of a liquid, and / or a gas, or as a refrigeration system of the walls of the evaporation chamber 10. Also, in another application, when the gas injected into the liquid contained in the chamber comes from the ambient air, the device illustrated in FIG. 10 can advantageously be used as air conditioning, discharging into the ambient air outside the evaporation chamber 10 the air cooled from evaporation. By way of example only, it is for example possible to cool air at 20 ° C. (temperature of the air injected at the inlet of enclosure 10) by lowering its temperature to 10 ° C. the air at the outlet of the chamber 10) by injecting it into the evaporation chamber 10 of the air at 20 ° C. under a pressure of 2 bars, with a flow rate of 8 Vs (approximately 30 m3 / h) said enclosure containing liquid water at an initial temperature of 19 ° C. it is for example possible to cool air at 40 ° C (air temperature at the inlet of the enclosure 10) by lowering its temperature to a temperature between 16 ° C and 19 ° C (temperature of the at the outlet of the enclosure 10) by injecting it into the evaporation chamber 10 of the air at 40 ° C. under a pressure of 2 bars, with a flow rate of 5 I / s, said enclosure containing liquid water at an initial temperature of 19 ° C.

FIG. 11 shows an application of the invention in which an installation 6 similar to that of FIG. 9 is used as a heat source for a conventional heat pump 7, in order to rapidly reduce the energy of the medium outside the evaporator of the heat pump, which increases the efficiency of the heat pump. FIG. 12 - cooling of a gas with possible gas depollution FIG. 12 shows an evaporation device 1 '' according to the invention and allowing the rapid cooling and, if appropriate, the depollution of a gas to This device 1 '' comprises means for replacing the liquid 11 contained in the evaporation chamber, which makes it possible to supply the evaporation chamber 10 with liquid at a temperature below the temperature of the liquid contained in the evaporation chamber. in the evaporation chamber 10, and to evacuate the liquid contained in the evaporation chamber. These liquid renewal means comprise, for example, an intake pipe 14 'and a pump 15' for introducing the liquid into the evaporation chamber 10, and an outlet pipe 16 'and a pump 15' for the pumping the liquid outside the evaporation chamber 10. The gas at high temperature is introduced into the liquid 11 through the bottom of the evaporation chamber 10. The evaporation of the liquid 11 makes it possible to absorb the stored in the gas whatever its temperature, this energy is recovered in the form of steam, which can then be used to produce electricity, after separation of the cooled gas and the steam at the outlet of the enclosure. Evaporation 10. The renewal of the liquid in the evaporation chamber 10 with cooler liquid makes it possible to evacuate, outside the enclosure 10, a portion of the calories accumulated in the liquid, and to avoid a rise in excessive temperature of the liquid 1 1 Another content of this device is to allow the dissolution in the liquid of pollutants contained in the gas which is injected into the liquid.

After passing through the liquid 11, the gas is decontaminated. This device can for example be used for the cooling and the depollution of a gas resulting from an incinerator and which can have a temperature of several hundreds of degrees, the passage of the gas in the liquid making it possible to block the propagation of the pollutants in the atmosphere.

Claims (55)

REVENDICATIONS1. Device for evaporation of a liquid, comprising an evaporation chamber (10) intended to contain a liquid to be evaporated and supply means (12) for introducing a gas into a liquid (11) to be evaporated contained in the evaporation chamber (10), so as to form gas bubbles in the liquid and promote the evaporation of the liquid. 2. Device according to claim 1, wherein the supply means (12) comprise a compressor (121), a pipe (120) for admission of a gas into the compressor (121) and an outlet pipe (122). ) allowing the injection into the liquid (11) to evaporate the gas delivered by the compressor (121). 3. Device according to any one of claims 1 or 2, wherein the supply means (12) can automatically regulate the feed rate of the gas entering the evaporation chamber (10). 4. Device according to any one of the preceding claims, wherein the evaporation chamber (10) is at atmospheric pressure. 5. Device according to any one of the preceding claims, comprising means (PV), allowing a depression of the evaporation chamber (10). 6. Device according to any one of the preceding claims, comprising liquid renewal means for supplying the evaporation chamber (10) with liquid and discharging liquid contained in the evaporation chamber ( 10). 7. Device according to claim 6, wherein the means (15; 14; 16) of liquid renewal can supply the evaporation chamber (10) with liquid at a temperature above the temperature of the liquid contained in the evaporation chamber (10). 8. Device according to claim 6, wherein the means of renewal in liquid (14 '; 15'; 15 "; 16 ') allow to supply the evaporation chamber (10) with liquid at a temperature below the temperature liquid contained in the evaporation chamber (10). 9. Device according to claim 6, wherein the liquid renewal means comprise in the evaporation chamber (10) one or more liquid outlet openings (100b), preferably positioned near the bottom (100). of the enclosure or in the bottom (100) of the enclosure. 10. Device according to any one of claims 6 to 9, wherein the liquid renewal means are adapted to automatically regulate the flow of liquid entering the evaporation chamber (10). 11. Device according to any one of claims 6 to 10, wherein the liquid renewal means comprises a hydraulic pump (15) for a forced supply of the evaporation chamber (10) in liquid. 12. Device according to any one of claims 6 to 11, wherein the liquid renewal means comprise a supply line (14) which is adapted to form a liquid column, and whose upper end communicates with the liquid. evaporation chamber (10), and a hydraulic pump (15) for forced liquid supply of said supply line (14). 13. Device according to any one of claims 6 to 12, wherein the liquid renewal means are designed to pump water in a natural environment, including sea water, water from a lake. or water from a watercourse, or groundwater. 14. Device according to any one of the preceding claims, wherein the gas injectable in the liquid is air or a mixture based on air. 15. Device according to any one of the preceding claims, wherein the gas for injection into the liquid comprises helium. 16. Device according to any one of the preceding claims adapted to evaporate a volume of liquid water. 17. Device according to any one of the preceding claims, adapted to evaporate a volume of liquid at an evaporation temperature below the boiling point of the liquid. 18. Device according to any one of the preceding claims, adapted to evaporate a volume of liquid water at an evaporation temperature of less than 100 ° C, preferably less than 50 ° C, and more preferably still less than 25 ° C. . 19. Device according to any one of the preceding claims, air conditioner function, wherein the gas injectable in the liquid is ambient air, and which allows to evacuate into the ambient air outside the enclosure. evaporating (10) the cooled air from the evaporation. 20. Installation for treating a liquid by evaporation and condensation of this liquid, said installation comprising an evaporation device which is referred to in any one of the preceding claims, and wherein the upper part of the evaporation chamber. (10) for containing steam communicates with a condensing system that condenses the steam from the evaporation chamber (10). 21. Installation according to claim 20, allowing the production of electrical energy, and wherein the condensation system (3) is used to condense the steam from the evaporation chamber (10) and recover the energy of this condensation by turning it into electrical energy. 22. Installation according to claim 21, wherein the condensation system uses a Kalina cycle, or a Uehara cycle or a Rankine cycle, or a cycle derived from one or other of these cycles. 23. Installation according to any one of claims 20 to 22 comprising a receptacle of the liquid from the condensation of steam. 24. Installation according to any one of claims 20 to 23 wherein the evaporation chamber (10) of the evaporation device is fed with water pumped in a natural environment, including sea water, water from a lake or water from a watercourse, or groundwater. 25. Installation according to any one of claims 20 to 24, wherein the gas supply means (12) for injecting air into a liquid contained in the evaporation chamber by taking all or part of of this air in the ambient air. 26. Installation according to any one of claims 20 to 25, wherein the gas supply means (12) can recycle the gas from the evaporation chamber by re-injecting all or part in the enclosure evaporation. 27. A method of evaporation of a liquid, characterized in that a liquid (11) to be evaporated is introduced into an evaporation chamber (10), and a gas is introduced into the liquid contained in the enclosure of evaporation (10), so as to form gas bubbles (13) in the liquid and promote evaporation of the liquid. 28. The method of claim 27, wherein the evaporation chamber (10) is at atmospheric pressure. 29. The method of claim 27, wherein the evaporation chamber (10) is depressed. 30. A method according to any one of claims 27 to 29, wherein the pressure is automatically regulated in the evaporation chamber (10) above the liquid (11). 31. Process according to any one of claims 27 to 30, during which the flow of gas entering the liquid (11) is automatically regulated. 32. Process according to any one of claims 27 to 31, during which a portion of the liquid (11) is continuously replaced in the evaporation chamber (10) with new liquid. 33. The method of claim 32, during which a portion of the liquid (11) is continuously replaced in the evaporation chamber (10) with new liquid at a temperature greater than the temperature of the liquid contained in the enclosure. Evaporation (10). 34. Process according to claim 32, during which part of the liquid (11) is continuously replaced in the evaporation chamber (10) with new liquid at a temperature below the temperature of the liquid contained in the enclosure. Evaporation (10). 35. Process according to any one of claims 32 to 34, during which the flow of liquid entering the evaporation chamber (10) is automatically regulated. 36. Process according to any one of claims 27 to 35, wherein the gas introduced into the liquid (11) is air or a gaseous mixture based on air. 37. Process according to any one of claims 27 to 36, wherein the gas introduced into the liquid (11) comprises helium. 38. Process according to any one of claims 27 to 37, in which a volume of liquid is evaporated at an evaporation temperature lower than the boiling point. 39. Process according to any one of claims 27 to 38, wherein the liquid (11) contained in the evaporation chamber (10) is water. 40. The method of claim 39, wherein the water is evaporated in the evaporation chamber (10) at an evaporation temperature of less than 100 ° C, and preferably less than 50 ° C, and more preferably less than 25 ° C. 41. Process according to any one of claims 27 to 40, wherein the liquid (11) contained in the evaporation chamber (10) is water pumped in a natural medium and in particular seawater, water from a lake or water from a watercourse, or groundwater. 42. Process according to any one of claims 27 to 41, during which the liquid vapor produced is condensed in the evaporation chamber (10). 43. The method of claim 42, wherein recovering the condensation energy of the steam. 44. The method of claim 43, wherein the vapor condensation energy is recovered and converted into electrical energy. 45. Process according to any one of claims 42 to 44, during which the liquid resulting from the condensation of the vapor is recovered. 46. Process according to any one of claims 27 to 45, during which a portion of the gas injected into the liquid (11) to be evaporated is air taken from the ambient air. 47. A method according to any one of claims 27 to 46, wherein at least a portion of the gas injected into the liquid (11) is recycled by being reinjected into the liquid to be evaporated. 48. A method according to any one of claims 27 to 46, wherein the gas injected into the liquid is air taken from the ambient air and in which it is discharged into the ambient air outside the enclosure. evaporation (10) the cooled air resulting from the evaporation. 49. A method according to any one of claims 27 to 47, wherein the gas injected into the liquid is a hot gas, and in that the gas is cooled by evaporation of the liquid contained in the evaporation chamber (10). ). 50. Use of the device according to any one of claims 1 to 19 or the process according to any one of claims 27 to 48 for cooling the liquid contained in the evaporation chamber (10). 51. Use of the device according to any one of claims 1 to 19 or the method referred to any one of claims 27 to 49 for cooling the gas injected into the liquid contained in the evaporation chamber (10). 52. Use of the device referred to in any one of claims 1 to 19, or the installation referred to in any one of claims 20 to 26 or the method referred to in any one of claims 27 to 49, to produce energy from the steam produced, and more particularly to produce electrical energy. 53. Use of the device according to any one of claims 1 to 19, or the installation according to any one of claims 20 to 26 as a heat pump or as a heat source of a heat pump. 54. Use of the device according to any one of claims 1 to 19, or the installation according to any one of claims 20 to 26 or the method referred to in any one of claims 27 to 49, for treating a liquid containing a component and for separating said component of the liquid by evaporation and condensation. 55. Use of the device referred to in any one of claims 1 to 19, or the installation referred to in any one of claims 20 to 26 or the method referred to in any one of claims 27 to 49, to produce drinking water from salt water contained in the evaporation chamber.