FR3031581A1 - DEVICE FOR PRODUCING WATER BY CONDENSING EFFECT OBTAINED BY CONDUCTING THE HEAT OF A HEAT TRANSFER FLUID - Google Patents

Abstract

The present invention relates to a device for producing water (10a) by a condensation effect, said device comprising at least one heat transfer fluid container (11a-11b) capable of storing heat energy, at least two heat exchangers ( 12a-12b) fixed to the at least one container (11a-11b) and able to recover the heat energy contained in said container (11a-1b), a network of heat-transfer wires (16a) connected solidly and thermally heat exchangers (12a-12b) and able to cause a condensation effect between a first temperature stored by the at least one container (11 a-1 1b) and a second temperature sensed by said heat transfer son network (16a), and a reservoir (15) for collecting water capable of storing water from said network of heat transfer wires (16a).

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to a device for producing water by a condensation effect. BACKGROUND OF THE INVENTION The invention finds a particularly advantageous application for producing water in arid and desert areas with large temperature variations, for example between day and night. STATE OF THE ART It is known to produce water by using the condensation effect that occurs by contacting hot air on a cold surface or by contacting cold air on a hot surface. Known devices use electrical means for heating or cooling a condensing surface capable of producing the condensation effect.

However, these devices use electrical means to heat or cool the condensing surface which wear over time thus limiting the use of this type of device in arid and desert areas for which maintenance operations can be complex in because of the difficulties of the field.

OBJECT OF THE INVENTION The present invention aims to overcome the drawbacks of the prior art by proposing a device for producing water by a condensing effect without using electrical means for heating or cooling a condensation surface. For this purpose, the invention relates to a device for producing water by a condensation effect, said device comprising at least one heat transfer fluid container capable of storing heat energy, at least two heat exchangers attached to the at least one container and able to recover the heat energy contained in said container, a heat transfer son network connected solidly and thermally to the heat exchangers and able to cause a condensation effect between a first temperature stored by the at least one container and a second temperature sensed by said heat transfer son network, and a water collection tank capable of storing water from said network of heat transfer son. The invention thus proposes a device for producing passive water which in preferred embodiments can be implemented without electrical means. According to one embodiment, the device comprises a flask configured to contain a gas. Thanks to these provisions, the balloon can be inflated with hot air or helium so as to raise the device in the air. Once elevated the device can collect water from moist air masses and cloud masses.

According to one embodiment, the device comprises at least one isothermal protection means movable between two positions: a first position in which the at least one container is covered by said isothermal protection means, and a second position in which the at least one container is not covered by said isothermal protection means.

According to one embodiment, the heat exchangers are made by rods whose material is able to effectively conduct hot or cold, preferably copper. According to one embodiment, the heat exchangers are made by tubes whose material is able to effectively conduct hot or cold, preferably copper. According to one embodiment, the tubes are in hydraulic communication with the fluid of the at least one container. According to one embodiment, the tubes are hollow and pass through the at least one container without the fluid of the at least one container entering said tubes. According to one embodiment, the heat transfer son network comprises horizontal heat transfer son which are connected solidly and thermally to the heat exchangers via other heat transfer son.

According to one embodiment, at least one heat exchanger comprises means for guiding the liquid captured by the wires towards said reservoir. According to one embodiment, the device comprises a flow slope adapted to direct the liquid captured by the heat transfer son towards said tank.

BRIEF DESCRIPTION OF THE FIGURES The invention will be better understood by means of the following description, given for purely explanatory purposes, of the embodiments of the invention, with reference to the figures in which: FIG. a device for producing water by a condensation effect in a front sectional view according to a first embodiment of the invention; - Figure 2 illustrates the water production device of Figure 1 in a view FIG. 3 illustrates a device for producing water by a condensation effect in a front sectional view according to a second embodiment of the invention; FIG. 4 illustrates a device for producing water; water by a condensation effect in a front sectional view according to a third embodiment of the invention, and - Figure 5 illustrates, schematically and in section, a device for producing water according to a fourth embodiment of the invention. realization of the inventio not.

DESCRIPTION OF EXAMPLES OF THE INVENTION It is already noted that the figures are not to scale. Figures 1 and 2 illustrate a device 10a for producing water by a condensation effect according to a first embodiment. The device 10a comprises two containers 11a, 11b of heat transfer fluid. The first container 11a is located in an upper part of the device 10a relative to the ground 17 while the second container 11b is located in a lower part. The first container 11a is fixed on a high support 26 maintained by lateral uprights 25 and the second container 11b is fixed by a low support 27 held on the same uprights 25. These containers 11a, 11b are made to receive the solar radiation S to heat the coolant during days of sunshine or to store a cold heat energy. Each container 11a, 11b comprises a series of juxtaposed tubes 5 comprising a filling opening 19 and a drain plug 20. For example, for a device 10a 2.5 m high and 4 to 6 m wide, the device 10a may include rigid polyvinyl chloride tubes (acronym for PVC) of high density and 60 to 80 mm in diameter. The tubes of the containers 11a, 11b are traversed by heat exchangers 12a, 12b, for example copper rods or hollow copper tubes. These heat exchangers 12a, 12b are interconnected by a network of heat transfer wires 16a extending between the high supports 26 and low 27. In addition, some son 16a may be arranged horizontally. This network of wires 16a captures the coolness of the air flow V blowing during the night so as to create a heat shock between the heat of the wires 16a heated by the tubes of the containers 11a, 11b and the coolant of the air flow V This thermal shock makes it possible to create a condensation effect along the wires 16a. Alternatively, the device may be protected from a blast of too much natural airflow that may dry out the water produced by the condensation before it reaches the storage tank. The tubes of the container 11b located on the low support 27 are traversed by the heat exchangers 12b so that the condensation water captured by the network of heat transfer wires 16a flows into a water collection tank 15 positioned between the 27 and the ground 17. For this purpose, the end of the heat exchangers 12b is provided with a means 14 for guiding the liquid. Preferably, the high 26 and low 27 supports are covered with an isothermal coating capable of limiting the heat losses of the containers 11a, 11b. 3 illustrates a second embodiment of the invention in which the device 10b has only one container 11c of heat transfer fluid positioned on a high support 26 while the uprights 25 extend beyond the high support 27 until at the height of the tubes of the container 11c. An isothermal protection means 18 is fixed on the uprights 25 and makes it possible to protect the tubes of the fluid container 11c at night. This isothermal protection means 18 must therefore be removed during the day to effectively heat the coolant contained in the tubes of the container 11c. The tubes of the container 11c are traversed by heat exchangers 12c extending parallel to the uprights 25 in the direction of the ground 17. The network of heat transfer wires 16b form a mesh connected along the heat exchangers 12c on the part extending under the 27. The end of the heat exchangers 12c is provided with a liquid guiding means 14 capable of directing the liquid captured on a flow slope 21. The flow slope 21 then directs the liquid into a reservoir 15 collection of water buried under the ground 17.

In one embodiment, the heat exchangers 12c are made by copper tubes filled with the coolant and plugged at their ends. The condensation then forms around the tubes. Alternatively, the heat exchangers 12c can be made by hollow copper tubes passing through the tubes of the container 11c. The condensation is then formed inside the tubes of the heat exchangers 12c and the air circulates in the tubes of the heat exchangers 12c. In one embodiment, the isothermal protection means 18 comprise openings so that the upper end of the tubes of the heat exchangers 12c is in contact with the air located above the isothermal protection means 18 when the isothermal protection means 18 are positioned on the container 11c. Figure 4 illustrates a third embodiment of the invention wherein the device 10c comprises three containers 11d, 11e and 11f heat transfer fluid in the form of liquid tanks. Two containers 11d and 11e are arranged on lateral uprights 29 of the same height and a container 11f is disposed on a central upright 28 whose height is less than the height of the lateral uprights 29. The containers 11d, 11e and 11f are made by a bottom and isothermal side walls surmounted by a glass lid. The containers 11d, 11e fixed on the lateral uprights 29 are connected to the container 11f fixed on the central upright 28 by two heat exchanger networks 30a and 30b. In the same manner as in the embodiment of FIG. 3, each network of heat exchangers 30a, 30b can support a network of heat transfer wires. In one embodiment, the heat exchangers 30a, 30b are made by copper tubes filled with the fluid contained in the containers 11d, 11e and 11f. For this purpose, the bottom of each container 11d, 11e and 11f 3031581 6 comprises fluid exchangers 12d, 12e, 12f and 12g able to take or inject the fluid from the heat exchangers 30a and 30a into the containers 11d, 11e and 11f . To limit the flow of fluid, the circuits are equipped with control valves 22a, 22b, 22c and 22d.

A lower portion of the heat exchangers 30a, 30b directs the captured liquid to two flow slopes 21. The flow slopes 21 then conduct the liquid into a buried water collection tank 15. The containers 11d , 11e and 11f can also be protected by isothermal protections. The invention thus makes it possible to recover the water contained in the ambient air by a condensation effect by storing a heat energy at a first temperature in containers and by restoring this heat energy when the ambient air has changed to a second temperature. The invention can be used by storing the heat of the ambient air during the day and producing water at night when the outside temperature is much lower than that of the day. Similarly, the invention can be used by storing the coolness of the night and producing daytime water with the difference in temperature. The invention can also be implemented in these two modes cyclically. Alternatively a heating or cooling system of at least one container may also be implemented to improve the performance of the device. A heating system may include thermal resistors installed in a container and connected to a solar panel. A cooling system can be achieved by a refrigerant device of the fluid flowing in a container. This heating or cooling system can be operated at critical times for which a large amount of water has to be produced. In particular embodiments, the heating system comprises hydraulic turbines that produce energy by taking advantage of the elevation of the device, for example as shown in FIG. 5. A particular configuration of the heating system consists of parabolic mirrors configured to concentrate the heat of the sun on a heat conductive material in contact with a coolant stored in an isothermal tank. These embodiments have the advantage of not requiring a fuel supply. In particular embodiments, the heating system is a water heater supplied with oil, gas, or a heat pump, for example. In embodiments, the water heater utilizes a stand-alone power source, such as a battery. In a particular configuration, the heating system is powered by electricity supplied by a battery, a wind turbine or a photovoltaic panel. In a variant, the device may comprise a pump capable of creating a closed-circuit circulation of the fluid used between the different heat transfer containers making it possible to improve the efficiency of the thermal exchanges of the device. The pump is preferably fed by a complementary installation type 10 wind or solar panels. Figure 5 illustrates a fourth embodiment of the invention. In this particular embodiment, the device has a balloon 31 configured to contain a gas, such as hot air or preferably helium. Thus inflated, the balloon can elevate the device into the air which then forms an aerostat that can be used to collect water from moist air masses or cloud masses at altitude. In this particular embodiment, two heat transfer fluid tanks 11g and 11h are disposed in the center of the device, at least two heat exchangers 12h and 12i are attached to the reservoir and connected to a heat transfer son network 16c. A water reservoir 15 collects water formed by condensation on the device, this reservoir 15 has a flow slope 21 conveying water to the reservoir by gravity. The lower part of the water tank 15 is connected to a tube 34 which conveys the water to the ground. The passage of water between the water tank 15 and the tube 34 is regulated by a valve 33. The valve 33 may have several states, open, closed or partially open. The control of the valve is on the order of an operator or in an automated manner. In a preferred embodiment (not shown) a sensor is used to measure a value representative of a physical quantity, for example the weight or the height of the volume of water contained in the tank. The transition from one state of the valve to another can be done when a measured quantity reaches a predetermined threshold. At least one attachment cable 32 mechanically connects the balloon 31 to the rest of the device. In embodiments (not shown), the device comprises a defrosting system on the means for collecting and flowing water. The defrosting effect can be achieved by mechanical action and / or application of heat and / or use of liquid or dry chemicals designed to lower the freezing point of the water, for example different salts or brines. , alcohol, glycol. One embodiment of the mechanical defrosting system is a pneumatic defroster consisting of alternately swollen and emptied rubberized fabric chambers. In preferred embodiments (not shown), the water reservoir 15 comprises an isothermal protection means which is configured to limit the heat exchange and to shelter the water from the wind in order to avoid evaporation and / or water gel contained in the water tank 15. The isothermal protection means 10 covers at least a portion of the water tank 15 and may comprise resin, polyester and / or plastics such as polyethylene. In embodiments, the protection means has two reversible faces, a first face whose surface promotes the absorption of heat and a second face whose surface reflects the thermal radiation.

In preferred embodiments (not shown), the aerostat device is connected to the ground by cables. At least one winch adjusts the length of the cables. In embodiments (not shown), the aerostat device includes means for regulating the gas pressure in the balloon 31. In one embodiment, the regulating means comprises a helium inflator or an air burner. and a valve that allows the gas to escape. These arrangements allow the aerostat device to adjust its altitude to compensate for variations in the weight of the device in particular due to the accumulation of water in the water tank 15.

In embodiments (not shown), the tube 34 is connected to at least one hydraulic turbine. In embodiments (not shown), the device comprises at least one thermal conductor thread configured to diffuse by radiation the heat of the coolant transported in the pipes to the ambient air. In preferred embodiments, the net is configured to promote the formation of drops of water. This net may comprise fibers consisting of polymethyl methacrylate and or fibers which have a spindle structure configured to promote the agglomeration of water drops.

Claims (10)

REVENDICATIONS1. Device for producing water (10a-10d) by a condensation effect, characterized in that it comprises: - at least one heat transfer fluid container (11a-11h) capable of storing heat energy, - at least two heat exchangers thermal devices (12a-12i) fixed to the at least one container (11a-11h) and able to recover the heat energy contained in said container (11a-11h), - a network of heat-transfer wires (16a-16c) firmly connected and thermally to the heat exchangers (12a-12i) and able to cause a condensation effect between a first temperature stored by the at least one container (11a-11f) and a second temperature sensed by said heat transfer wire network (16a-16c ), and a water collection reservoir (15) capable of storing water from said network of heat transfer wires (16a-16c). The water producing device of claim 1 which includes a balloon (31) configured to hold a gas. 20 3. Device for producing water according to claim 1, which comprises at least one isothermal protection means (18) movable between two positions: a first position in which the at least one container (11a-11h) is covered by said isothermal protection means (18), and a second position in which the at least one container (11a-11h) is not covered by said isothermal protection means (18). 4. Device for producing water according to claim 1 to 3, wherein the heat exchangers (12a-12i) are formed by rods whose material is adapted to effectively conduct hot or cold, preferably copper . 5. Device for producing water according to claim 1 to 3, wherein the heat exchangers (12a-12i) are formed by tubes whose material is adapted to effectively conduct hot or cold, preferably copper. 303 15 81 11 The water generating device according to claim 5, wherein the tubes are in hydraulic communication with the fluid of the at least one container (11a-11h). 5 7. Device for producing water according to claim 5, wherein the tubes are hollow and pass through the at least one container (11a-11h) without the fluid of the at least one container (11a-11h) penetrates in said tubes. 8. A device for producing water according to one of claims 1 to 7, wherein the 10 heat transfer son network (16a-16c) comprises horizontal heat transfer son (16a-16c) which are connected securely and thermally to the heat exchangers (12a-12i) via other heat transfer wires (16a, 16c). 9. A device for producing water according to one of claims 1 to 8, wherein at least one heat exchanger (12a-12i) comprises a guide means (14) of the liquid captured by the heat transfer son (16a-16c ) towards said reservoir (15). 10. Device for producing water according to one of claims 1 to 9, which comprises a flow slope (21) adapted to direct the liquid captured by the heat transfer son (16a-16c) towards said reservoir (15) .