FR2952388A1 - Autonomous device for production of electricity and water, has mast including air inlet opening located at base of mast and air outlet opening located at top of mast to generate and/or promote circulation of air inside mast - Google Patents

Abstract

The device has a producing unit i.e. wind generator, for producing energy in autonomous manner. A mast (2) of the producing unit is utilized as one of elements permitting to recover water present in ambient air. The mast includes an air inlet opening (2-1) located at a base of the mast, and an air outlet opening (2-2) located at the top of the mast to generate and/or promote circulation of air (A) inside the mast. A flap adjusts flow of the air circulation through the openings.

Description

The present invention relates to a mixed device for producing electricity and producing water, the power generation device being preferably autonomous as well as the water production device. The device allowing the production of energy autonomously such as a wind turbine will have its mast adapted according to the invention so as to recover the water present in the ambient air and thus produce water, preferably, in a way that is also autonomous. Field of the invention The field of the invention is that of autonomous energy production and the recovery and / or production of water. 2. The prior art To recover water from the ambient air, some dew collecting devices have already been tested, for example the placement of nets placed vertically in the peaks having an atmosphere often loaded with "fog" of the Andean Cordillera or the installation of roofs to collect dew water. There are also condensing dehumidifiers to dry wet rooms. The dehumidifier may be, for example non-limiting, a heat pump dehumidifier, dehumidifying fan type or Peltier effect. These devices give encouraging results but have several disadvantages, such as that of having a low efficiency for dew collectors or that of recovering at the same time the dust present in the ambient air or to come into conflict with the means -2- production of electrical energy such as solar panels also installed on the roofs. To produce energy autonomously, there are already solar panels, wind turbines producing electrical energy. With regard to wind turbines, there is already undesirable condensation inside the various elements and in particular inside the mast. A device has already been proposed (patent No. EP1736665 (A2) to overcome this inconvenience but not to transform the mast of the wind turbine into a real device to produce water in greater quantity possible, which is a main objective In the same way, the patents FR 2833044 and WO 2004/099685 describe machines for producing water by condensation of water vapor using wind energy, but its machines are rather machines specifically adapted to the production of water contrary to the present invention which makes it possible to give an additional function to an existing equipment 3. Objectives of the invention The object of the invention is in particular to overcome these main drawbacks of the prior art. It is an object of the invention to allow the production of water in places where the water is not present naturally.Another object of the invention is to reduce the price of water. the cost of overall energy and water production in relation to energy production and water production carried out by separate means. Another objective of the invention is to avoid multiplying the installations by producing energy and water by the same "machine" such as a wind turbine. Another essential objective of the invention is to produce water in a non-polluting manner and to benefit from the strong ongoing development of renewable energy sources. For example, it is planned to install a large wind farm in arid regions of Africa, and to install this park with wind turbines adapted according to the invention, would help this continent to partially solve its water shortage.

A further object of the invention is to treat waters unfit for consumption and make them drinkable. 4. Main Characteristics of the Invention To achieve these objectives, the main characteristic of the invention will consist in using at least one element of an equipment allowing the autonomous production of energy to implement an autonomous production device. water. The invention relates to the implementation of means for producing water autonomously by adapting at least one element and / or equipment of an autonomous means of producing energy of the wind type, for example non-limiting but preferential the mast element of the wind turbine, so as to create a flow of air inside said mast and promote the condensation of the water contained in the ambient air. To avoid multiplying the facilities the said at least one means of recovering the water in the ambient air uses at least a subset of the means for producing energy autonomously as a non-limiting example using the pylon or mast of a wind turbine as a chimney for the production of water by condensation. -4- The autonomous power generation equipment or will be able to be advantageously associated with at least one battery. Most photovoltaic systems have special batteries (stationary batteries with lead alloys) that store the energy generated by the photovoltaic panels in anticipation of periods when there is no sun. These batteries are designed to restore a stable current for long periods while maintaining their recharging abilities, and this on a number of occasions (cycles), we speak of stationary or deep cycle batteries. In order to improve and increase the production of water, the invention also relates to the possibility of implementing a control device in order to make it possible to recover water by condensation cycles as a function of parameters, as for example non-limiting, hygrometry of the ambient air and / or the charge of the stationary batteries. More precisely, a wind turbine will have its mast transformed so as to produce inside it an upward air flow. To produce this upward air flow, it is necessary to create openings at the base and at the top of the mast which may be named later in the document "air inlet device" for an opening placed towards the base. of the mast and "air outlet device" for an opening placed towards the top of the mast. These openings will preferably be calibrated and / or adjustable so as to produce an optimum updraft to reach the dew point. Improvements may be made such as the placement of a dew-point coating within the mast and the flow of water thereby produced. The device can be improved by the introduction of adjustable openings and / or a "vacuum cleaner" fan to control the flow of air inside the mast depending on, for example non-limiting, the degree of hygrometry of the ambient air. The device can be improved by filtering the air at the inlet and / or by passing it through an evaporator before circulating it through the cold zone. The device can also be improved by compressing this air in the condensation receptacle. The device can also be improved by installing inside the mast, several plates, hollow or not, preferably placed vertically. These plates can be advantageously replaced and / or supplemented by cylindrical surfaces. These cylindrical surfaces will be, preferably, placed vertically and concentrically and be honeycombed to allow better air circulation. These plates and / or these cylindrical surfaces can be advantageously replaced and / or supplemented by lighter threads, less cost. A wind turbine mast generally consists of a plurality of cylindrical and / or tapered parts assembled to one another. To obtain a greatly increased water production, at least one of these so-called cylindrical and / or conical parts can advantageously be converted into a heat pump dehumidifier or a dehumidifying fan type. Placed preferentially at the upper part of the mast, the said cylindrical part and / or conical heat pump dehumidifier, will transform, by heat exchange, a part of the moisture contained in the air in condensed water . The efficiency can be improved by completing the installation with one or more stationary type batteries charged when the wind turbine produces energy, this or these batteries in turn supplying the water production system when the wind turbine does not. is more active for lack of wind for example. The dehumidifier system will be placed in such a way that the heat exchange at the heat pump produces refrigeration in the lower volume and warming up in the higher volume. The air will heat up the mast which will naturally develop a vertical suction and strengthen the airflow in the mast. The high mast height is also an asset to naturally produce an upward flow of air. At least one of these cylindrical and / or conical parts can be advantageously converted into a collector of the condensation water and thus give the mast a "water tower" function. This part of the "water collecting" mast will preferably be placed at a lower level than the dehumidifier system part. These two parts of the mast, dehumidifier system and water collector, are constructed to ensure the initial functions of the mast such as to allow access to the other elements of the wind turbine located above the mast. The dehumidifier system and the water collecting equipment can also be adapted to be mounted in existing masts.

Such a wind turbine transformed as described above in the description may be placed near and / or above a source of water unfit for consumption so as to use the natural evaporation of this water for to increase the production of drinking water in this wind turbine. The evaporation can be promoted by placing above this water a heating surface such as for example non-limiting, a surface composed of transparent materials that will use the heat produced by the sun to generate a strong evaporation by greenhouse effect. The water vapor thus produced can be collected and conveyed to the inlet of the "water production chimney" system of the wind turbine. 5. List of Figures Other features and advantages of the invention will appear more clearly on reading the following description of a preferred embodiment, given by way of a simple illustrative and nonlimiting example, and the accompanying drawings. , of which - Figure 1 shows the essential elements of a wind turbine (1) which are the mast (2), the foundations (3), the coupling cabinet to the electrical network (4), the hub and control of the rotor (5), the steering system (6), the generator (7), the nacelle (8), the electric regulation system (9), the multiplier (10), the brake (II) and the blade ( 12). Figure 2 shows a wind turbine mast (2) adapted according to the invention. Two openings (2.1) and (2.2) placed respectively downward and upwardly of the mast (2) of the wind turbine allow a flow of air (A) inside this mast. In order to promote an upward flow of air within, the air inlet opening (2.1) placed towards the base of the mast is oriented preferentially towards the prevailing winds while the air outlet opening (2.2) placed towards the top of the mast is preferentially oriented in a direction opposite to that of the prevailing winds so as to use the outward wind to create a suction effect, which can be compared to an effect of "pump", between these two openings. These openings are, preferably, calibrated to allow optimum air circulation within the mast to obtain the dew point. A flow system (2.4) is preferably located spirally around the inside of the mast. At the base of this flow system, a manifold (2.3) conveys the water to the tank (2.5) placed inside the mast. FIG. 3 presents a wind turbine mast (2) adapted according to the invention as in FIG. 2 but with an air circulation inside the mast made more efficient by placing a "vacuum" fan (2.16) at near at least one of the two openings, preferably close to the opening (2.2) placed towards the top of the mast. The circulation of the air is regulated by controlling the operation of the "vacuum" fan (2.16) by an electronic control and / or control system (2.6), so as to favor the obtaining of the dew point on the elements of collecting water inside the mast. - Figure 4 shows a wind turbine mast (2) adapted according to the invention. Depending on the direction of the wind, given by the orientation system (6) of the wind turbine, the electronic control and / or control system (2.6) has opened at least one opening (2.1), whose orientation approximates the direction of the wind, among a plurality of openings (2.1), in the example four openings (2.1) equipped with flaps (2.7) located towards the base of the mast and opened at least one opening (2.2), whose orientation approaches the direction opposite to that of the wind, among a plurality of openings (2.2), in the example four openings (2.2) equipped with shutters (2.7) located towards the top of the mast. In order not to weaken the structure of the mast, said four openings (2.1) are arranged at different levels towards the base of the mast and the four openings (2.2) are arranged at different levels towards the top of the mast. To ensure a similar flow inside the mast whatever the pair (2.1) and its opposite (2.2) open, the opposite openings (2.1) and (2.2) are arranged in the mast so that the four distances (D1), (D2), (D3), and (D4) between the openings (2.1) and their opposite openings (2.2) are identical. Said four openings (2.1) are placed, with respect to a horizontal section of the mast, preferably at an angle of 90 ° relative to each other, the four openings (2.2) being placed towards the top of the mast with the same orientations as the openings (2.1). The at least two openings (2.1) and (2.2) thus open and placed respectively downwards and upwards from the mast (2), allow air circulation inside this mast. The electronic control and / or control system (2.6) adjusts these openings, preferably, to allow optimum air circulation in the mast to obtain the dew point. A flow system (2.4) is preferably placed spirally around the inside of the mast. At the base of this flow system, a manifold (2.3) conveys the water to the tank (2.5) placed inside the mast. - Figure 5 shows a wind turbine mast {2) adapted according to the invention. The air flow is controlled by an electronic control and / or control system (2.6) which controls the two openings (2.1) and (2.2) equipped with adjustable flaps (2.7) placed respectively downwards and upwards. mast (2) in order to obtain as often as possible condensation of air on the inner surfaces of the mast. Air circulation can be advantageously made more efficient by placing a "vacuum" fan (2.16) near at least one of the two openings. To increase the condensation surface, plates (2.9), cellular or not, are preferably placed vertically inside the mast. - Figure 6 shows a similar arrangement to Figure 5 but the inner plates (2.9) are replaced by cylinders (2.10), preferably dimpled to allow a good flow of air. - Figure 7 shows a similar arrangement to Figure 5 but the inner plates (2.9) are replaced by threads (2.11) lighter and thus easier to arrange in the mast. - Figure 8 shows a wind turbine mast (2) adapted according to the invention. A heat pump (2.12) and the condensate collector (2.14) are preferably installed towards the top of the mast and near the outlet (2.2) to facilitate the flow of water. evacuation of air that has lost its moisture after passing through the heat pump. An electronic control and / or control system (2.6) makes it possible to put the heat pump (2.12) into operation when the conditions are optimal, such as, for example, non-limiting, when the degree of humidity in the air reaches a certain level. rate and / or when the so-called stationary type battery (2.15) is sufficiently charged. The electronic control and / or control system (2.6) also regulates the operation of the heat pump by controlling the flow of air inside the mast (2) with the aid of the vacuum fan (2.16) and two openings (2.1) and (2.2) equipped with adjustable flaps (2.7) placed respectively at the bottom and at the top of the mast. - Figure 9 illustrates the supply and / or the supply of a greenhouse (13) in water. by means of a wind turbine (1) whose mast (2) is modified according to the invention, as previously described in FIG. 8, to support a heat pump system (2.12) of the dehumidifier type as well as a collector of the condensation water (2.14) preferably placed upwardly of said mast (2) giving said mast a water tower function. The water is also produced by condensation on the inner face of the mast, as previously described in the presentation of Figure 2 or Figure 3. A flow system (2.4) is preferably placed in a spiral around from inside the mast. At the base of this flow system, a manifold (2.3) conveys the water to the tank (2.5) placed inside the mast. This greenhouse (13) can also be powered by the wind turbine (1) in energy. - Figure 10 shows a single element Peltier effect (14). FIG. 11 shows a similar arrangement to FIG. 5, but Peltier elements (14) are placed on the inner plates (2.9) in order to substantially increase the production of water. An electronic control and / or control system (2.6) also regulates the operation of the Peltier effect elements (14) when the conditions are optimal, such as, for example, non-limiting, when the degree of humidity in the air reaches a certain level. rate and / or when the so-called stationary type battery is sufficiently charged and / or by controlling airflow inside the mast (2) using the "vacuum" fan (2.16) and the two openings (2.1). ) and (2.2) equipped with adjustable flaps (2.7) placed respectively at the bottom and at the top of the mast. FIG. 12 shows the diagram of an air condenser of the dehumidifier type composed of a compressor (15.1), a condenser (15.2) and a fan (15.3) for sucking up humid air (15.5) through condenser (15.2) and return dry air (15.6), and a recovery tank (15.4) condensed water. 6. Presentation of a preferred embodiment of the invention In this example of implementation, the autonomous device for producing water is associated with a greenhouse. The autonomous electricity generating device is constituted of a wind turbine (1) modified according to the invention as described above in the description in FIG. 8. The electricity produced by the wind turbine supplies, from preferentially, a heat pump system (2.12) dehumidifier type for condensation of moisture contained in the ambient air, this air is preferably collected outside the greenhouse. The electricity produced by the wind turbine also charges a stationary type IO battery (2.15). When the wind turbine no longer supplies enough energy, an electronic control and / or control system (2.6) switches the power supply of the elements necessary for the water production device such as the pump system. heat (2.12), the "vacuum" fan (2.16) and adjustable flaps (2.7), preferably to the complementary source of energy that is the at least one so-called stationary type battery (2.15).

A heat pump dehumidifier directs the air, through a fan, to a first heat exchange coil. This first coil reaches almost the freezing point. The water contained in the air condenses on this coil and can then be recovered and directed to a condensed water collector (2.14), then to one of the "watering" systems of the greenhouse which may include a reservoir. A second heat exchange coil warms the air. The air thus heated and dried 30 may advantageously be blown into the parts of the wind turbine or the proper operation of the equipment requires a degree of hygrometry as low as possible. The periods of the year when the temperatures are relatively low, it will also be possible, advantageously, to breathe in the greenhouse and heated air and help maintain the air of the greenhouse to a desired temperature. The heat pump dehumidifier releases the heat generated by the compressor and the fan motor into the air, in the upper part of the mast for example, in addition to rejecting the heat produced by the dehumidifier. water from the vapor state to the liquid state. This heat thus restored can also be advantageously blown into other parts of the wind turbine and / or in the greenhouse. The water is also produced by condensation on the inner face of the mast, as previously described in the presentation of Figure 2 or Figure 3.

Claims (11)

REVENDICATIONS1. Autonomous device for producing water, comprising at least one means for producing energy autonomously of the wind turbine type (1), implemented using the mast subassembly of said wind turbine as one of the elements of this device for recovering the water present in the ambient air characterized in that said mast (2) comprises at least one opening (2.1) located towards the base of said mast and at least one opening (2.2) located towards the top said mast to generate and / or promote air circulation (A) inside said mast (2). 2. Device according to claim 1, characterized in that said openings (2.1) and (2.2) are dimensioned so that the flow rate of the air circulation (A) promotes the obtaining of the dew point on the inner surfaces of the said mast to recover the water present in the said air flow (A). 3. Device according to claims 1 and 2, characterized in that said openings (2.1) and 2.2) comprise elements, as a non-limiting example, type shutters (2.7) for adjusting the flow rate of the air flow ( A) through these openings, these flow control air flow control elements being controlled by an electronic control system and / or control (2.6). 4. Device according to claims 1 to 3, characterized in that the flow rate of the air circulation (A) can also be advantageously made more effective and better controlled by placing a "vacuum" fan (2.16) inside the mast near at least one of the two openings, more precisely that placed towards the top of the mast. 5. Device according to claims 1 to 4, characterized in that an electronic control system and / or control (2.6), depending on the wind direction given by the orientation system (6) of the wind turbine , pilot the opening of the "air intake device" (2.1) whose orientation is closest to the wind direction, among four openings (2.1) equipped with flaps (2.7) located at different levels towards the base of the mast and controls the opening of the "air outlet device" (2.2), whose orientation is closest to the direction opposite to that of the wind, among four openings (2.2) equipped with shutters (2.7). ) located at different levels towards the top of the mast. 6. Device according to claim 5, characterized in that the distances (DI), (D2), (D3) and (D4) between the openings (2.1), located at different levels towards the base of the mast, and their openings opposite (2.2), located at different levels towards the top of the mast, are identical and the flow rate of the air flow (A) is similar to the inside of the mast regardless of the torque (2.1) and its opposite ( 2.2) open. 7. Device according to claims 1 to 6, characterized in that the flow rate of the air flow (A), preferably ascending, obtained inside said mast and the nature of the surfaces inside this said mast promotes the obtaining of the dew point on at least the inner face of this mast or on other flat or cylindrical surfaces, honeycombed or not placed vertically inside said mast, or on nets stretched, preferably vertically, in said mast. 8. Device according to claims 1 to 7, characterized in that a channel (2.4), placed as a downward spiral on the inner face of said mast, allows to promote the collection of condensed water and its routing for to be stored to a tank (2.5). 9. Device according to claims 1 to 8, characterized in that the air flow (A), preferably ascending, obtained inside said mast passes through at least a portion of said mast 15 advantageously converted into dehumidifier heat pump type or dehumidifying fan type, this or these "dehumidifier" parts being placed at the upper part of the mast. 20 10. Device according to claims 1 to 9, characterized in that the air flow (A) obtained inside said mast passes through at least a portion of said mast where Peltier effect elements (14) are arranged on inner plates (2.9) and put into operation by an electronic control and / or control system (2.6). 11. Device according to claims 1 to 10, characterized in that said mast (2) has at least one part advantageously converted into a collector of the condensation water (2.14) which thus gives the mast a function " water tower".