FR3008453A1 - IMMERSE DEVICE FOR DELIVERING TIME OR TIME DIFFERENCE CYCLIC LINEAR ACCELERATION TO A REST FLUID IN A VERTICAL CYLINDER IN AN AUTONOMOUS MANNER - Google Patents

Abstract

Device immersed to give a desired moment or deferred in time, cyclic linear acceleration to a liquid fluid at rest in a vertical cylinder, autonomously. The invention relates to a device for giving, at a desired time or deferred in time, a linear and cyclic acceleration to a liquid fluid at rest in a cylinder, for driving a mechanism or a hydraumotrice turbine, autonomously. It consists of a cylindrical tank 1 of a fully immersed energy well, comprising a bell 7 freely circulating like a piston, equipped at its top with a valve 8, composed of a valve 10 sliding vertically to close a 9. The bell 7, immobilized at the bottom of the vertical cylindrical tank stores air 24 to rise, according to Archimedes principle, once released by setting in motion the liquid fluid in which it bathes. On ascending, the bell 7 pushes the liquid fluid 21, above it, to expel it 5 by a transfer pipe 6 and sucks the liquid fluid 30, below it, which arrives by a tubing of suction 5 by driving for example a hydro-motor turbine (31).

Description

The present invention relates to a totally immersed device, to give at a desired moment or deferred in time, a cyclic linear acceleration to a fluid at rest in a vertical cylinder, autonomously. The linear acceleration given to a fluid at rest in a vertical cylinder 05 is traditionally and, to our knowledge, always obtained by means of a mechanism that consumes external energy during this phase. The object of the present invention relates to a device totally immersed in a liquid fluid to overcome this disadvantage called "10 energy well"; in what follows to facilitate the explanations we will consider that the liquid fluid is water. It is constituted according to a first characteristic of a vertical cylindrical tube closed at its ends which is completely immersed stabilized at the bottom of a natural or artificial reservoir, for example, by several guyings distributed around its periphery; the vertical cylindrical tube communicates with the water of the container by its lower end by at least one suction pipe and its upper end communicates with at least one transfer pipe capable of capturing the water which escapes from it; the vertical cylindrical tube comprises inside a bell which circulates freely like a piston, with at least one valve at its top constituting an "air drain hatch". Said valve is in particular composed of a valve, equipped with a seal; the valve flap in the open position, rests in a cradle; the latter comprises a "valve stem" integral with the valve which it passes through and which slides in its lower part, under the said valve, in a guide welded to the center of the cradle, itself welded on a lattice integral with the inside the bell; an "upper cup" and a "lower cup" welded respectively to the upper and lower ends of the rod, respectively allow to close and open the flap of the air drain flap, when they come into contact with end stops of the sliding of the bell located at the bottom and at the top of the vertical cylindrical tube. The lower cup of the valve stem serves to position the bell, in the lower position, the latter being then maintained, during the injection of air into the bell, into the bottom of the vertical cylindrical tube, with the aid of locking means in sufficient numbers located on its periphery; these locking means are capable of being mechanically retracted. The bell is filled with air by an "inflation pipe", opening at the base of the vertical cylindrical tube, equipped with an inflation stop device when, for example, for example, the air volume in the bell reaches a predetermined value. The vertical cylindrical tube is maintained during this operation at the bottom of the water by its shrouds, so that it does not rise when the bell fills with air. When the bell is filled with air, the locking means which held the bell at the bottom of the vertical cylindrical tube open and release the bell, full of air, at the desired moment, which rises freely, according to the principle of Archimedes, by pushing the water located above it and which is expelled from the vertical cylindrical tube by at least one transfer pipe, while water is sucked by at least one suction pipe which is associated, by for example, in series with a hydro-motive turbine. The diameters of the collection and suction manifolds are calculated to have regulated and selected flow rates. The upward movement of the bell can be interrupted by its abutment at the top of the vertical cylindrical tube; The cup comes into contact with a stud that stops it in its ascent and action, while the body of the bell, still containing air, continues to rise and pushes the valve to open the drain hatch. air, before stopping its rise when the valve is positioned in the cup. It will thus be sheltered from turbulence during the gravitational descent of the bell until the air is completely evacuated by the air drain hatch. This allows the bell to go down by its own weight; during the descent of the bell the flap of the air drain flap 20 rests by simple gravity in its cradle so as not to be reassembled and go close the air drain hatch, which would stop the descent of the bell. When the bell arrives towards the bottom of the cylindrical tank, the lower cup of the valve comes into contact with a stud which stops it in its descent, thus allowing the valve to be lifted by the valve stem whose cup is secured; 25 while the body of the bell continues its descent to come to rest on the valve by closing the air drain hatch, and to stop; the locking means of the bell, in the low position, which had been retracted during the release of the bell at the beginning of the cycle let the bell pass and then went into the locking position, keeping the bell in a low and resting position on the pad, waiting to be filled with air, then released to start a new cycle of fluid circulation. According to particular embodiments: - The cylindrical tank of the "energy well" can be manufactured in metal boiler or plastic recycled or not, and having a smooth inner wall. It can also be made from molded concrete slabs, into which can also be embedded, for example, crushed plastic bottles. Its density must be greater than 1 to stay in the water, at the bottom of the natural or artificial reservoir. An obanage is recommended to stabilize it and mmobilisen - The bell can also be manufactured in boilermaking, smooth on his pe periphery outside. It circulates freely, almost just for the purpose, like a piston, in the tank and will have a density greater than 1 so as to be able to descend by garvity to the bottom of the well. It should be sufficiently rigid to avoid deforming once filled with air. 05 The valve can also be made in boiler. The valve is equipped with at least one flexible gasket to prevent air leakage, to allow its storage without self-discharge system. Fig. 1 represents a schematic demonstration of the device according to the invention, in free air, in which a fluid flows without effort in the two vertical cylinders connected in a closed circuit, driven by a volume of calibrated air, according to FIG. principle of Archimedes. Fig. 2 is a partial schematic view of FIG. 1 which shows that the fluid also circulates without effort in the vertical cylinder, when it is totally immersed in an aquatic environment, for example. FIG. 3 represents the device, according to the invention, totally immersed, Fig.2, equipped with hydro-motor turbines, driven by the circulation of a fluid. Fig. 4 shows the device, totally immersed, assembled in series to substantially increase the volume of the fluid to be simultaneously moving, or, alternatively (as shown in the figure). FIG. 5 shows the device in section with an internal mechanism (the bell) in several operating positions, according to the phases: high position, descent configuration, low standby position. Fig. 6 shows the device, in section, completely immersed, with a bell in descent configuration, reset phase, and in the low position. FIG. 7 shows the device, totally immersed, with a locked bell, in the air filling phase, and waiting to start operation when the time comes. Fig. 8 shows the fully submerged sectional device with a bell, in the mid-run phase, which creates a fluid flow for driving a hydrautromotor turbine. Fig. 9 shows the device in section, fully immersed, with a bell in the high position phase and end of the cycle, to release the air that it contains, and, be ready for the descent phase. Fig. 10 shows the device, fully immersed, equipped with a buffer stock, immersed, compressed air at very high pressure (300 Bars, for example) to reduce the air loading time of one or more bells of several "energy wells", for example. Referring to the drawings of Rg.5 to 9, the device, nt immerge, consists of a vertical cylindrical tube 1 closed at its ends 2 and 3 which is completely submerged and stabilized at the bottom of a natural or artificial reservoir by several guying 4, 4 bis, at the monis, distributed around its periphery; the vertical cylindrical tube 1, communicates with the water of the natural or artificial reservoir, by its lower end 2 by at least one suction pipe 5 and its upper end 3 communicates with at least one transfer pipe 6 05 capable of capturing the water that escapes from it; the vertical cylindrical tube 1 comprises inside a bell 7 which circulates freely like a piston, with at least one valve 8 at its top constituting an "air drain hatch" 9. The said valve 8 is notably composed of a valve 10, equipped with a seal 11; the valve 10 of the valve in the open position 12, rests in a cradle 13; the latter comprises a "valve stem" 14 integral with the valve 10 which it passes through and which slides in its lower part 15, under the said valve 10, in a welded guide 16 in the center of the cradle 13, itself welded on a lattice 17 integral with the bell 7; An "upper cup" 18 and a "lower cup" 19 welded respectively to the upper 20 and lower ends 21 21 of the rod 14, respectively allow to close and open with the valve 10 of the air drain hatch 9 , when they come into contact with the top 22 and bottom 23 end stops of the sliding of the bell located at the bottom 2 and at the top 3 of the vertical cylindrical tube 1. The lower cup 19 of the rod 14 serves to position the bell 7, in the low position Fig: 5, 6, 7, the latter being then maintained, during the injection of air 24 into the bell 7, in the bottom of the vertical cylindrical tube 1, by means of locking 25, 25 bis in sufficient numbers located on its periphery; these locking means 25, 25a may be mechanically retracted, for example, at the appropriate time, by means of "control means", to allow the release of the bell 7 in the upward direction, and let the bell 7 freely under the pressure of its own weight on the descent. The bell 7 is filled with air 24 Fig: 7 by "an inflation pipe" 26, opening at the base of the vertical cylindrical tube 1, equipped with an inflation stop device 27 when, for example, the volume of 24 air in the bell reaches a predetermined value. The vertical cylindrical tube 1 is maintained during this operation at the bottom of the water by its stays 4, 4 bis, at least, so that it does not rise when the bell fills with air. When the bell 7 is filled with air 24, the locking means 25, 25 bis which held the bell at the bottom of the vertical cylindrical tube 1 open and release the bell 7, full of air, which rises freely, according to the principle of Archimedes Fig: 8, by pushing the water 21 located above it and which is expelled from the vertical cylindrical tube 1 by at least one transfer pipe 6, while water 30 is sucked by the minus a suction pipe 5 which can be associated in series with a hydro-motor turbine 31. The diameters of the transfer and suction pipes 5 are calculated to have regulated and selected flow rates.

The upward movement of the bell 7 can be interrupted by its abutment at the top 2 of the vertical cylindrical tube 1; Fig: 5, 9 The "upper cup" 18 comes into contact with a high block 22 which stops it in its ascent and action, while the body of the bell 7, still containing air, continues its rise and pushes the valve 10 to open the St air drain trap »9, before stopping its rise when the valve 10 is positioned in the cradle 13. It will thus be protected from turbulence until the air ( it is completely evacuated by the air discharge hatch 9, and during the gravitational descent of the bell 7. This allows the bell to descend by its own weight, during the descent of the bell 7 the valve 10 of the bell air drain hatch 9 rests by simple gravity in its cradle 13 not to be reassembled and go close the air drain hatch which would stop the descent of the bell 7. When the bell 7 arrives to the bottom 2 of the cylindrical tank 1, Fig: 5,6,7, the lower cup 19 of the valve comes into contact with a pl and bottom 23 which stops 15 in its descent, thus allowing the "lifting" of the valve 10 by the valve stem 14 whose cup 19 is secured; while the body of the bell 7 which continues its descent until it comes to rest on the valve 10 by closing the air drain hatch 9, and to stop; the locking means 25, 25a for the bell 7, in the low position, which had been retracted during the release of the bell 7 at the beginning of the cycle, let the bell 7 pass and then went into the locking position, automatically or programmed, now the bell 7 in the low position and resting on the stud 23, waiting to be filled again with air, then released, when the time comes, to start a new fluid circulation cycle.

In order to increase the working power of the moving fluid, Fig.4 the bells 32, 33 and 34, in three cylindrical tanks 35, 36 and 37 connected in series, are released one after the other to increase the circulation time. overall fluid, or simultaneously to increase the available power (not shown) but decreasing the time of use, for hydro-motor turbines 38 and 39 for example. The cylindrical tank 1 of the submerged energy well, FIG. 10, can be supplied with compressed air with a tank 40 of 1 or 2 m 3, for example of high pressure, for example 300 bar, whereas 1 bar per ten meters. 1 bar is only necessary (4 bars at 30 meters depth, for example) to fill the bell 41, see the three bells 32, 33 and 34, in the configuration in Fig. 4. This reserve makes it possible to absorb overcapacity in compressed air and to shorten the filling time of the bells in order to maximize the efficiency of the "energy well" installations. FIG. 1 shows that the device according to the invention functions perfectly, except when it is immersed according to the Archimedes principle by using two interconnected and closed vats 42 and 43 and where a bell 44 is raised in the tank 41 to give without effort, a linear acceleration to a fluid 45. In Fig: 2 only the tank 42 is immersed, thus using the environmental fluid, showing that the linear acceleration of a fluid 45 is also found within the tank, the fluid being admitted by the low inlet pipe 46 and expelled by a high transfer pipe 47, on which hydro-motor turbines 48 and 49 may be installed, for example, in FIG. In manufacturing methods of the "energy well", the vertical cylindrical tube 1 can be manufactured in metal or plastic boiler (even from 10 recycled plastic bottles). It can also be made from molded concrete slabs, in which also drown bottles, plastic, crushed. Its weight should preferably be greater than 1 to stay at the bottom of the water, in an aquatic use, for example. Several guyings are recommended to stabilize and immobilize the bottom of a natural or artificial reservoir. The bell 7 can also be manufactured in boilermaking and have a density greater than 1 so as to be able to go down by garvity at the bottom of the well. It must be rigid enough to avoid distorting a faith filled with air. The valve (s) will also be made in boilermaking and the valves will be equipped with seals to prevent air leakage.

The device according to the invention is particularly intended to give, at a desired moment or time, a linear cyclic acceleration to a fluid at rest in a vertical cylinder, autonomously. 25 35 7

Claims (7)

CLAIMS1 / Device for creating a flow of fluid inside a vertical cylindrical tube (1), fully immersed, activated by a bell (7) flowing freely as a piston. 2 / Apparatus according to claim 1, characterized in that it consists mainly of a bell (7), comprising at least one valve (8) for storing a reserve of air (24) and power automatically release this air at the end of the cycle. 3 / Device according to claim 2, characterized in that the valve (8) is composed of a valve (10) having at least one seal (11) and 10 to open or close a drain hatch air (9). 4 / Apparatus according to claims 1 and 2, characterized in that the valve (8) is fixed firmly to a lattice (17) held integrally inside the bell (7) and allowing the fluid to circulate. 5 / Device according to claims 1, 2, 3 characterized in that the valve (8) 15 comprises a "valve stem" (14) integral with the valve (10) through which it slides in its lower part ( 15), under the said valve (10), in a welded guide (16) in the center of the cradle (13), itself welded on a lattice (17) integral with the bell (7). 6 / Apparatus according to any one of the preceding claims, characterized in that the valve (8) is actuated automatically to close the air flap (9) with the valve (10) by pushing the rod (14). ) upwards when the cup (19) comes into contact on the stud (23) during the descent, by gravity, of the bell (7) which thus comes to rest. 7 / Apparatus according to any one of the preceding claims, characterized in that the valve (8) is actuated automatically to open the air drain flap (9) by pushing the valve (10) on the cradle (13). ), and the rod (14) downwards when the cup (18) comes into contact with the stud (22) during the rise of the bell (7) which thus comes to rest thus allowing the air s' escapes through the air drain hatch (9). 8 / Apparatus according to the preceding claim, characterized in that the bell (7) released from the air it contained, down to the bottom of the vertical cylindrical tube (1) by gravity, allowing free passage of the fluid by the air drain flap (9) is open, while the flap (10) is protected from turbulence in the cradle (13). 9 / Apparatus according to claim 8, characterized in that the bell (7) at each rnqntée, by the action of the air (24) it contains pushes the fluid it has over- above it (21) expelled by a transfer pipe (6) calibrated and sucked by at least one suction pipe (5) which can be associated in series with a hydro-motor turbine (31). The diameters of the transfer (6) and suction (5) tubings are calculated to have regulated and selected flow rates. 10 / Apparatus according to claim 9, characterized in that the liquid fluid flow created in the vertical cylindrical tube (1), which can be captured at the outlet of the transfer tube (6) or return of the suction pipe (5), is an energy capable of moving materials, such as, for example, a hydro-motor turbine. 15