FR2615569A1 - SOLAR AUTONOMOUS ATMOSPHERIC PUMP - Google Patents

Abstract

The present invention comprises the integration into a drilling or a well of a ballast covered at its top part with a plastic cap permeable to solar radiation to use the absorbing power of metal which is made stronger by surface treating the metal, the green house effect produced, supplying with calories an air volume imprisoned at the atmospheric pressure and its temperature and which, increasing in volume and therefore in temperature and by adding vapor to increase the number of moles in the expanding gas, will create the pressures required to the pumping out of water, also for a predetermined volume, which is imprisoned by means of valves and flushing systems.

Description

The pre-invention consists in producing an autonomous solar atmospheric pump intended for the dewatering of
water for consumption or irrigation in climates
Mediterranean or tropical, very sunny, this A
any depth, between levels: - t meter a
- 200 meters and even more theoretically, either in
wells, boreholes OR in littoral border in any region
particularly desert, provided that a groundwater or
underground river or any water source to wind up
exist.

The principle is a gas application
perfect, following the equation of state of the ga of CLAPEYRON
PV = nRT using the pressure that can exert
saturated steam at a corresponding temperature T and
produced.

The invention therefore consists of a tube (1>) called
: "ballast" of length greater than depth a
reach, weld, or flange at the joints in case of connections,
according to the techniques used by oil tankers, in steel,
copper, and generally in all materials-drivers of
heat, likely to withstand strong pressures
external movements (ground movements and abrasion), and / or,
internal (gas). The dimensioning being adapted to the required depth conditions, the conditions
climate and flow requirements.

 The tub @@ or ballast, (2) of variable diameter.

often adapted to drilling conditions, from 100
mm. and of appropriate length as the case may be, is closed
each end (3) by semi-spherical caps
flanged or welded which makes it completely watertight
steam, and capable of withstanding a maximum pressure of 30 bar.

 The upper cap has (4) its blade: an opening, also variable in diameter, for receiving a small tube (5): input / output, average diameter of 40 mm and average length: 300 to 500 mm, able to withstand the same constraints as the ballast on the quality of the fittings.

 The outer end of the small tube, intended to be immersed. () will be protected by a fixed strainer, or floating if it is possible to predict the low water level.

 The strainer will itself be protected by a plastic weave at this perforated location, (7) used for recouvuvrement part of the ballast (8) for the purpose of retaining the insulation (9) incorporated cellular glass, which will increase therefore the overall final diameter of at least 100 m / m> as a function of the desired insulation coefficient in the buried part (10 10). ).

 At the other end of the small tube, ie in the inner part of the ballast (11), a non-return valve, control (12) by a float itself secured to another float slightly less than the diameter of the tube (36) intended to separate the two fluids, will let the water to a specified set point under the pressure of the water table (13).

This non-return valve can advantageously be replaced by an electro valve controlled by sensors if one can have a source of electrical energy, even low, such as the use of photocells. (14
The other end of the ballast, it is destined to come out of the earth of the order of 3 to 5 meters on average vertically (15)> or with an inclination (16) corresponding to a better optimization of the insolation, according to thermodynamic requirements at the level of the desired temperature exchanges.

 The ballast in its aerial part, as for the buried part, is coated with cellular glass shells, this time serving, not anymore of insulator, but of light absorber thanks to its satisfactory properties of "black body" - a special high temperature black paint covers (18), in addition, the surface of this cellular glass for the aerial part thus increasing the effects of solar spectrum absorption.

 In countries extremely hot, we can usefully refrain from placing this cellular glass for the aerial part, a simple wash of the special black paint on the hull of the ballast will be sufficient.

 On the hull or on the cellular glass there will be placed (19), below the mid-height, a blackened copper tube too, of small internal diameter, approximately 12 mm> and suitably twisted so that it can not There is no problem of low point, to favor a maximum gravitation of the vapor which will be formed in it. This copper coil will have a length of 75 to 100 meters, ie a capacity of: 7 to 12 liters of water, one of the ends of this exchanger being connected to a tank of large capacity (20) about 1 m3 of water, fueled by the overflow of the atmospheric pump, and which must be initiated on the day of start.Cette tank or "tank" will be placed such that its water level is halfway up the copper crown so that the it is always half full (21) or in case of unexpected drop in the tank level there is still some water in the crown. (22). A special valve on the fitting (24) blocks the supply of ean from the coil until the pressure of the ballast is opted for, to open again and replenish the boiler.

 The other end of the copper tube will be introduced with the resistance precautions already described in the top of the ballast about 50 cm from the pole on the most accessible side by a reservation (23).

Finally all the aerial part of the ballast will be bagged in a special long-lasting plastic film of 30 or 65 microns thick, very transparent to the solar spectrum, except in the far infrared which already ensures an optimized greenhouse effect. This envelope or "sleeve", will be retained by a system of hoops (24) creating a relative stiffness and to move away from the wall of the ballast a few 70 mm (25) to create a blade of air. In certain cold but sunny regions, a second sleeve (26) of slightly greater diameter: 60 mm, covering the former, may be created, which will prevent heat losses as a result of the infra red rebroadcasts of the ballast and act as an insulator.

The ends of the sleeve will be ligated onto sealed cushions around the inlet / outlet pipe of the air (27) and the ballast (28).
The small pipe attached to the pole of the aerial end of the ballast will be used to evacuate the steam initially introduced into the ballast, for the balancing of the water level inside the ballast, at the end of the cycle.

 A simple ping-pong ball connected by a rigid rod, carefully measured, (29) to the float of the water inlet flush will serve as a non-return valve (30) resistant to the pressure of 3n bars in the high position of the that there will be rise in pressure and opening automatically when the level of the float has reached its lowest run, thus allowing the filling of the water ballast and the renewal of air for the lowering of the temperature necessary to balance the system. The ball is introduced into a perforated tubular conduit (31) to allow the air to pass, a little larger than its diameter, and to fit on the collar of a jeint for sealing (32). The conduit has a dimension at least equal to the stroke of the float for water.

 Another insulating float (36), specially designed to separate the water front from the vapor-gas volume and sealed, will slide along the wall inside the ballast.This device will isolate the respective temperatures of the gas. hot and cooler water, thus avoiding excessive condensation of internal steam.

 The system described above is autonomous and reliable, nevertheless if we can have electrical energy possibly by solar cells, nothing would prevent its robotization by electro valves and appropriate regulation with pressure switch and servo motor.

 It will be understood the progress of the assembly when it will be known that a relatively small diameter pipe of the order of 20 to 40 mm depending on the dimensioning of the installation, leaving the base of the ballast (33) well below the low water level, near the lower cap and along - like the tracers, the outer shell of the ballast, will emerge at ground level (34) s>> from which we will see out by jerky ejections, we function of mounted in internal pressure, a quantity of water which should reach 8 m3 / day of which approximately 1 m3 recovered by an overflow, will be used for the production of saturating steam necessary. This steam, which in addition to the expansion of the air superheated by the exposure of the ballast to the sun, confined within the ballast enclosure, will create the pressure necessary to push the ballast water downward into the channel until it is quantitatively driven out in correlation with the variable powers obtained, due to the solar hazard.

When we know the problems posed by hunger in the world, which are almost always linked to the lack of water on the earth and which will always be lacking because of the demographic effects, it seems interesting to think that this invention will make an effective contribution to the exhaure of the water, in definite competition with the constraint pumping systems adapted but expensive already existing such as those requiring an important contribution of energy or distant transport and servitudes little adapted to the tropical sites: deserts, savannas .. It should be noted that the cost of installation, using solar cells, for the same diurnal effect, represents 10 times the cost of an installation that uses the AUTONOMOUS PUMP.
SOLAR ATMOSPHERIC, and probably will interest small hamlets of bush for domestic use or farmers in search of irrigation essential. Even nomads, could have great satisfactions if they could find water well fed and autonomous, since without supervision.

 It should be noted that a set of contiguous ballast batteries (35) would allow the water to be raised in stages, provided that a deep pressure ballast of sufficient depth is not available to eject the water at a sufficient depth. the surface. In this case the exhaure of the water would pass through several ballast judiciously calibrated so that the last and shallow is that which allows the water to reach the surface.

 The maintenance and the maintenance of the apparatus are non-existent, except in the case of electrical additions, it will be noted with interest that the tube put in place, could serve in case of necessity of replacement, casing of the drilling, and to allow the reintroduction of a new ballast after breaking down the hard-to-reach bottom of the one that has become obsolete.

Plate I reflects the different descriptions above with
Fig. I The general principle
Fig. 2: The inclined position (16)
Fig. 3: The battery system (35).

We will note in plate II ((One figure only), the alternative improvement that can be made to the overall efficiency, this thanks to a mi se work, nevertheless more delicate, if the "platform" of insulating separation (plate 1 - 36), made perfectly tight on its periphery, for example by cable glands ready, however, to slide along the wall of the ballast as soon as the pressure increases, is doubled by a similar fixation on the rod ( 29), at the level of the ballast which enters the earth (3! - the first being always at the level of water or almost. The assembly constituting a piston
(5) insulating by itself since it contains trapped air, colder indeed, but having no influence, on the hot part, that is to say aerial ballast, where o just the volume of the reduced air this time will increase more quickly in temperature, accelerating the duration of the cycle2 since the pressure necessary for the exhaure of the water will be more quickly reached.

Claims (8)

R E V E N D I C A T IO N S 1) Atmospheric pump using solar energy, (plate I) for the drainage of water, characterized in that it comprises: a tube intended to be partially embedded in the ground, (FIG. groundwater table (13) and whose upper part remains air (fi) and serves as ballast, air and steam, and the buried part of ballast, water (B). A set of valve and flush (27-32) at each tube end, connected by a rigid rod (29)> are controlled as soon as there is pressure loss and open at the same time. The pressure is produced by the expansion of the air, to which is added the steam obtained by a boiler (22) in the aerial part which enters directly into the upper part of the ballast (19). The evacuation of the water and its rise, operates through a small pipe parallel to the tube (33), always free. An insulating plate inside the tube fixed on the rod (36) separates the water from the steam. 2) atmospheric pump using solar energy according to claim 1 characterized in that i part of the tube is heat conductive material: the ballast is air (A) and covered with a suitable black paint or for countries little exposed or cooler of a solar absorber such as cellular glass shell, and a sleeve of plastic film transparent to the solar spectrum specially selected 26) creating the greenhouse effect. 3) solar energy using solar energy pump according to claim 1 & 2, characterized in that it comprises a coil (22) which surrounds the absorber tube. This coil called: boiler, produces steam that enters directly into the upper part of the ballast (23)> its level is maintained at mid-level by that of the water tank (20). 4) Atmospheric pump using solar energy according to claims 1 to 3, characterized in that, the buried body of the ballast (B)> sunk vertically in the ground which reaches and exceeds the level of the water table comprises insulation (10) itself covered with a tube (7). 5) Atmospheric pump using solar energy according to any one of claims 1 to 4, characterized in that the bottom of the ballast which receives the volume of water to rise in each cycle (B) has inside a flushing system (38) attached laterally below the level of the water table and a valve (11) which allows water to enter only if the float control (12) allows it, when the ballast is empty or at low water level. if the pressure did not drive everything away. This float itself is integral with a round insulating platform, whose diameter is slightly smaller than that of the ballast along which it must slide, and which serves to separate the fronts, water and air (36) .  6) Atmospheric pump using solar energy according to one  any of claims 1 to 5, characterized in that,  the inside of the ballast in the upper part comprises an external air inlet valve, at atmospheric pressure (32),> which a  closed by mechanical control in connection with the float (3 *,)> by a small piston which supports a light spherical shutter  40), when the pressure is exerted.Each cycle which comprises a set point (41) causes a water ejection (33 proportional in volume at the pressures exerted by the external exposure and at all the parameters temperature, volume, pressures , obtained and will be perpetuated as long as those-if will allow it during the day. 7) Atmospheric pump using solar energy according to any one of claims 1 to 6, characterized in that it comprises at the surface level and connected to it, a reservoir or tank (20) for retaining the solar energy. water and arrival thereof, a calculated volume to allow to feed the boiler (19) -not discontinuities. The tank at the top (43) has a  overflow which allows the water to flow, while in the lower part, a valve (24) against the return of steam, is arranged on the water pipe necessary for the boiler. Open it allows to supply the water level of the boiler (21). 8) atmospheric pump using solar energy according to claim 2> characterized in that, a protective greenhouse which relates to claims 1, 3, 4, 5, 6, 7, comprises a sleeve closed laterally in the direction of the length and which is retained by rings (24), for its maintenance diameter slightly larger than the diameter of the tube. The sleeve is sealed by ligatures (27-28) 9) Atmospheric pump using solar energy according to any one of the preceding claims 1 to 8, characterized in that, alternatively, and having in this case electrical energy, the use of electro-valves controlled by pressure switches, in response to the pressures exerted replace the sealing systems of claim 5. 10) atmospheric pump using solar energy according to claim 5. characterized in that, the insulating platform device for separation of the air and water fronts comprises two sealed trays, in applications of great depths, ( Plate II) one at the level of water (4) and the other connected by a rigid rod substantially at ground level (3), thus forming a real piston. The air trapped between the two trays serves as insulation (4).