FR3133217A1 - Energy Generator from the Gravitation Field - Google Patents

Abstract

The device, intended for the production of electrical energy, uses the gravitational field in a systemic operation based on simple principles of Physics. A looped chain, on a vertical support generally completely submerged, is formed of bases, each surmounted by a cylindrical and hemispherical envelope of variable volume. The bases connected together form a continuous sheath connecting the carrying envelopes each of a double assembly of beams mounted in scissors to develop by a double system of lever arms a force dependent on the position of a mobile mass as a function of its changes in exposure to the gravitational field, it causes on the communicating envelopes the continuous deployment of one of the vertical sections of the moving chain and simultaneously for the other a tightening. The first column, under the Archimedean thrust, involves this continuous chain movement driving an alternator group or any other equipment. 150 words Figure to be published with the abstract: figure 5

Description

Energy Generator from the Gravitation Field

In the context of the energy transition, the present invention concerns a device, which, through its operation subdivided into two complementary actions coordinated under the action of the gravitational field, makes it possible to produce mechanical and electrical energy. It does not contribute to the depletion of the planet's natural resources and does not emit or produce any polluting elements of any kind.

Technological background

Industrial energy production contributes significantly to global warming, which has major consequences. Others using the atom are the cause of serious, timeless pollution. The ideal clean energy, ready to be used in the majority of cases, is electricity; but its industrial production necessarily comes from a source energy. In this area let us first recall the classic fossil resources: coal - oil - gas - which, everyone knows, contribute to global warming, the reduction of their use is now more precisely programmed by the 1st Paris Agreement (12.12.2015) . Let us also mention uranium, used in technologies to meet considerable energy demands. But the costs of safety and dismantling problems, to which are added the potential risks of serious consequences for human health and for the environment, are various reasons which tend for the future to limit this means of production.

Let us also indicate the different resources, currently under development, which are part of the energy transition: - Farms using solar radiation which always remain dependent on periods and conditions of sunshine, they occupy a lot of land and mobilize large areas to the detriment agriculture or reforestation. When they can be installed in desert areas, they do not waste useful surface areas, but their distance from the areas of use reduces their productivity - Wind turbines, beyond the observation that they clutter and distort many landscapes, have a production which is even more uncertain, since their productivity is a function of climatological vagaries and also of the weakening of the winds at sunset, while paradoxically the demand for electric current increases simultaneously. These intermittent renewable energies require many more scientific and technical resources to secure the continuity of electricity production. There are other ways: biomass for example, but it subtracts arable land, often in areas where populations already do not have enough to eat. - Still little used, tidal energy is captured by the use of dams or tidal turbines; the energy production of these developments is periodic. To this nomenclature, we must add today the force of gravitation and therefore the important role that the permanent and continuous mass of our planet naturally plays.

Let us be interested in this gravitational field of the Earth, which remains invariable at each site 24/24 hours over 365 days maintaining the same intensity. Although this force varies somewhat depending on the region of the globe, it is of permanent intensity at every point on the planet. The broad use of this force can help to better respond to the major challenges of: water desalination, the depletion of certain natural resources as well as the decarbonization of the atmosphere and indirectly demographic and food problems. Knowing that the demographics are constantly growing, the general standard of living as a whole is increasing and if many remain undernourished, the demand for energy will always be growing significantly. The resource represented by the use of the gravitational field of the terrestrial globe (down to the geographical detail concerning its intensity) is of equal use for everyone on the globe. In this regard, the GEiCG device presented here requires installation in a maritime or aquatic site which cannot be a handicap, since water is present on 4/5 of the planet's surface.

This new device is a systemic operation involving the simultaneous implementation of means arising from the basic laws of Physics. The model presented below is a standard application of these rules. But this device cannot be designed without using different composite materials developed in particular throughout the 20/21st centuries. These materials contribute particularly to the growth of the tire industry as well as to the production of industrial canvases and fabrics allowing the manufacture of large, flexible and waterproof surfaces resistant to the high pressures required by the implementation of this device.

A brief description of the main elements of the device will then allow us to address the basic principle of the process used for the operation of the device, followed later by a more detailed description allowing an industrial approach.

GEiCG can be immersed in its majority or completely in an aquatic environment. It is made up of different elements forming a chain which wraps around a slender vertical support support ( ). This support is made of reinforced concrete (“overboard concrete” type) if necessary and contains one or more watertight boxes necessary for adjusting the balance of its flotation, another watertight closed volume (2) is intended to technical equipment. This fixed part of the device (in its upper and lower parts) is usually (except for particular applications) fixed to the bottom (figure 7) of the liquid space via anchoring cables (3) which are provided with a assembly (4) allowing the accommodation of their length. This arrangement is used when the device is located on a surface site, it can allow permanent monitoring of the flotation of the support support according to variations in the level of the liquid surface (tide, etc.).

This fixed structure which we will call "main support" receives two drums (5) one in the upper part, the second in the lower part, they are the direct supports of the chain made up of parallelepiped shaped elements each serving as a base ( 6) to a flexible cylindrical envelope (7) of variable volume comprising two open spaces contained between the hoops (32). The support and tension of the chain are carried by the vertical support and the drums, their spacing is adjustable by a jack mechanism, the chain is supported on the drums via neoprene plates fixed under the bases; the energy communicated by the chain is transmitted via the upper drum by gears to the receiving device located in the technical room.

The bases (figures 2 and 3) all identical, communicate with each other by flexible connections (8), a sheath is thus formed which runs through the entire chain through the bases, each opening on its cylindrical envelope of variable volume ECVV (7) which is dedicated to it. Its variability in volume is due to the particularity that it folds like an accordion.

Each link of the chain consisting of a base and an envelope is equipped with a double arm system of the BLAR retractable autonomous sink lever. Each BLAR system is made up of a double series of scissors joined together by axes ( ). The assembly is inserted into a framework frame (23) fixed to the base and to the structure of the ECVV. The force deployed by the BLAR system is communicated by the movements of a moving mass (9). These two BLAR systems equip each envelope symmetrically on either side, they are diametrically opposed ( ).

The main structures of the device are thus defined, before engaging in the basic theoretical principle of the operation of the device, let us recall that it was presented in a previous filing by the same author and therefore already known. The device is in principle completely submerged, the chain is the main element. It maintains the ECVV envelopes and puts them in gas communication with each other via the sheath already mentioned.

The development and folding of the ECVVs occur under the action of the BLAR systems each actuated by their own mobile mass (9) from which they receive force variations in direction and intensity depending on the exposures of the mobile mass (9) to the field of gravitation according to the sectors traveled during the rotation of the chain.

In the lower part of the chain, the exposure of 2 moving masses (9) to the gravitational field, with the resulting force on the BLAR, contributes to the opening of the envelope, while simultaneously 2 other moving masses act in the same way in the opposite direction to participate in the folding of an envelope which engages in the descent phase; the air from this other envelope is compressed and expelled into the sheath integrated into the chain and participates remotely in the deployment of the envelope which is presented in the assembled phase.

We notice that the air which is discharged circulates and descends through the duct to supply the opening envelope with the same volume and pressure. Furthermore, the rising circulation of air rises through the volume of the opening envelopes in this phase also supported by the deployment of the BLAR under the action of the mobile mass.

We thus see that the sheath always remains at constant pressure and volume. This internal pressure is established on an average between the high and low hydrostatic pressures of the liquid zone where the device is located.

Let us point out, however, that in practice we do not consider a difference in high and low pressure in the sheath considering the ratio approximately equal to 1/400 between the density of the air and that of the water.

By passing to the top of the chain the BLAR system changes position in relation to the gravitational field, which has the consequence of contracting the BLAR systems which cause the air to be expelled from the ECVV which is subject to them. This position of the BLAR devices is maintained throughout the descent phase, conditioning the ECVV envelopes in a blocked, closed position - As it passes down the chain, the BLAR systems change position again, triggering a new effect under the action of the masses mobile, they release their stress on the ECVV allowing the entry of air under pressure from the sheath, the BLAR lever arm only having to generate the complementary force necessary to overcome only the half hydrostatic pressure necessary for development of the ECVV approaching its rise phase.

The operating principle described, the description continues to examine the movements of the different devices constituting the chain. At its top as well as at its base are located the changes of direction for the bases (6), they are ensured by drums (5) whose axis is supported on the main support.

Tips (11) located below the bases fit into the notches (12) made in the rim (13) of the upper drum. At the bottom of the chain, the bases are guided in a large groove made around the circumference of the drum (5). Both on the upper drum and on the lower, the bases are supported on neoprene plates (30) or other similar material. The drums have several functions: maintaining the chain with the help of the hooks (11) and above all managing its tension. In addition, through a set of gears, the upper drum transmits the torque produced by the chain drive to the generator.

The bases, all of the same volume, are in communication with each other via a flexible connection (8) in the shape of an accordion which recalls the bellows between passenger wagons. This flexible connection and the base are the constituent elements of the closed network forming the watertight artery connecting all the ECVVs to each other.

The ECVV attached to the base empties or recharges its gaseous volume via a large by-pass (14) in communication with the looped hyperbaric artery ( ) constitutive like other ECVV and BLAR devices, of the continuous chain closed on itself.

To improve the hydrodynamics of the ECVV, its two bases (15) have an almost hemispherical shape, they are metallic. They are not included in the variable volume and are occupied by a neutral material (polystyrene type). The cylindrical periphery forming the flexible envelope may be from the elastomer family or similar. It is reinforced by different reinforcement hoops (32) and cables connected to the elements of the BLAR system. The use of materials which will prove to be durable and more economical to use will be the subject of special studies, particularly with regard to the aggressiveness of the marine environment.

The opening and closing of the ECVV are controlled by a double BLAR system, this “lever arm” function is carried out by retractable equipment ( ) which is reminiscent of certain corkscrews. This equipment which we have named BLAR ( autonomous retractable lever arm ) is equipped with a secured mobile mass (9). It is fixed at the level of the structure of the last scissor of the BLAR. Each BLAR device is made up of 2 parallel planes, each formed by a series of scissors. The two identical planes are connected by bars (16) which join the articulation points forming ball joints (17). The assembly thus produced forms a series of virtual volumes forming a line of rhombohedra (28). The common bars which connect two BLAR systems will be called coordinated axial bars (18). These first 3 axial BLAR bars are located opposite the hoops (32) which

determine 2 open spaces between them in the ECVV, the axial bars cross to join the BLAR symmetrically exercising the same function on the other side of this ECVV. Thus the development and folding of the ECVV are controlled by the simultaneous retraction or extension movements of the 2 BLARs which enclose the envelope according to particular arrangements allowing it to fit into a geometric assembly of constant decentering in order to avoid collisions. between BLAR devices of neighboring units. For this purpose by placing different angular values around the circumference of the envelope and also by a spacing allowing the intersection of the series close to the base with those which are distant from it, these relative positions are determined to address all the positions planned for the duration of the rotation cycle of the chain without collisions between the devices, The structures of the devices can thus be inserted among their similar ones of the following unit, this arrangement gives all the possibility of extension necessary for the BLAR device with a view to ultimately defining the characteristics of the device. These relative positions are determined to approach all relative positions during the duration of the chain rotation cycle without collisions between the devices (figure no. 5).

The mobile mass (9) which forms the end of the device is made up of high density materials of a metallic or other nature: e.g. lead rimmed or coated in steel (with protection for compatibility).

The basic constituent elements of the device having been presented, certain particularities of operation are discussed as follows:

The deployment and folding of the ECVV which are the basis of the process are produced under a double effect:

1 - The axial bars of the first elements of the BLAR device (18) are through, but also connected to the hoops (32) which structure the "fabric" of the ECVV envelope which has the consequence of subjecting the latter exactly to the movements of the elements of the 2 BLAR systems which surround it. Note that all the parts of the scissor system are totally connected and dependent on the movements of the mobile mass (9), which itself is subject by its mass to undergo the effect of the gravitational field depending on its position. During each cycle of the chain, this mobile mass alternately presents itself to the gravitational field in a first direction, then in the opposite direction, it therefore undergoes contrary actions of the gravitational force producing the contraction of the BLAR scissor system or at all contrary to the lengthening of it. It is easy to conclude that the deployment and folding of the envelope are linked to the sectors of the cycle traveled by the mobile mass close to the envelope to which it is dedicated.

2 - We note that the deployment of the ECVV is carried out under the action of the work of the BLAR, accompanied in this action by the induced force transmitted by the pressure of the sheath in a hyperbaric circuit; which helps to counter the hydrostatic pressure and allows the ECVV to inflate. Conversely, when the ECVV is compressed by the BLAR and retracts, this results in the folding and sudden reduction of the gas volume contained by the ECVV. The consequence is a compression, corresponding to the increase in pressure in the ECVV which causes a flush of air (or other gaseous combination which could be retained) towards the hyperbaric circuit, while the latter at the bottom of the chain is simultaneously relieved of an equivalent volume. We thus note that a continuous translation of gas takes place ( ) in the circuit between the closing ECVVs towards the opening ECVVs via the hyperbaric looped circuit.

The opening is therefore produced by the double effect due to the internal pressure of the hyperbaric gas loop network and by the moment applied by the BLARs. The opening of the ECVV therefore occurs at the bottom of the ascent sector and ends quickly because during the ascent phase the hydrostatic pressure external to the ECVV decreases in intensity.

Approaching the upper part, the base will come to rest on the drum via pads (30) in neoprene or other similar material, the hooks (11), which are fixed to it, are arranged to engage in the notches (12) of the rim (13) of the drum (5) of the upper part. Associated with gears, the drum communicates the kinetic energy of the chain to the calibrated alternator group, located in the technical room (2) of the upper part of the main support.

The ECVV has completed its rise, it still remains subject to the pressure of the hyperbaric circuit at an intermediate pressure between the high and low hydrostatic pressures. The ECVV envelope therefore remains developed, but must now begin its descent to fold. The BLAR system also deployed will, in this reversal of the chain, undergo the action of its mobile mass subjected directly to the force of gravitation. The contraction of the BLAR devices leads to the folding of the ECVV, the two hemispherical hulls (15) come together offering during the descent phase the lowest possible hydrodynamic drag like all the other phases of the rotation cycle of the chain.

Let us consider the operation of the deployment and folding of an envelope, it is dependent on the movements of the two mobile masses according to their orientation to the gravitational field whose direction of its action changes permanently during the cycle of the chain making the successive ones unfolding and folding of BLAR lever arm devices. The penultimate rhombohedral element (33) which is opposite the mobile mass directly activates the opening and closing of one of the half spaces of the envelope. The other half space is served by the last element (34) which is the mirror of its twin element (33); this second element is symmetrically mounted in relation to the fulcrum of the BLAR: the central axial bar (19). By this assembly, the force produced by the two symmetrical BLARs is equally distributed between the two paired elements in a simultaneous action in opening or closing of the entire envelope served by the two BLARs considered.

It will be noted that the on-board elements maintain the same mass, whether they are in the ascent or descent phase and that in one of these columns the ECVV envelopes have their cylindrical part deployed corresponding to a displaced liquid space causing a thrust equivalent Archimedes. In the other phase (closed ECVV), the column does not receive the same thrust, this results in an imbalance whose effect is to set the chain in motion, without any cause in its operation breaking this continuous imbalance.

The description of the operation of the device during the rotation cycle of the chain made it possible to analyze the movements of the constituent elements of the GEiCG. Note that they are generated according to the sectors of this cycle by the different forces brought into presence or produced by the pressures which underlie them and also by the effects of Archimedes' Thrust. All are directly or indirectly, depending on their orientation and their air or water environment, generated by the gravitational field which is therefore called upon here in a systemic mode resulting from a coordination of various actions.

- An envelope and its two retractable autonomous lever arms (BLAR)

A cylindrical envelope with its two hemispherical shells is shown accompanied by its two BLARs, one tightened in relation to the envelope and the other spread apart. More in the center, another BLAR appears which is linked and serves the neighboring envelope, its counterpart (light graphics) would be almost completely hidden behind the ECVV envelope shown here. Behind, the base corresponding to the envelope considered is also not shown.

- Axial section of a base and its envelope

This drawing corresponds to the AA cut shown on the , the envelope and the base at their common axis are seen in section. The main axial bar which crosses and maintains the envelope by joining its two BLARs is also sectioned in its thickness.

The support bars are also cut in the same plane. In the background also appear the reinforcement shelves, then the BLARs and the bars of the neighboring unit.

[Figure 3] - Partial view - rising phase

This section of the chain is located at the end of the rising phase when the bases with their deployed envelopes will engage on the upper drum. To make this drawing easier to read, the BLAR devices and their envelope are shown in the same color. We distinguish the bases joined by accordion connections and fixed together by coupling parts and ball joints. We can also see part of the bars which secure the frame frames (BLAR) and the envelopes to the bases constituting the chain.

[Figure 4] - Chassis-Running rails

This figure shows a typical section of a guide rail chassis which allows you to see the simple principle of internal bearing.

- General diagram of the chain - partial view

This diagram is limited to the upper and lower parts of the chain, locations where the movements of the equipment take place which involve variations in the volume of the ECVV envelopes. The different elements (in the foreground) of the chain are schematized by the use of a simple graphic which makes it possible to perceive the different opening and folding movements of the envelopes depending on the mobility of the mobile mass according to the direction of its movement. exposure to the gravitational field.

[Figures 6] - The support and its anchoring to the bottom

There shows the hanging position of the cables on the top and bottom of the support.

When the established position of the GEiCG device is flush with the upper level of the liquid space, it may be necessary to manage the altimeter of the device (maintenance, tide, etc.). Figure 7 shows the assembly with counterweight which can then be implemented.

The principle of operation of the chain can only be considered in relation to a stable and fixed support. Let us examine what contributes to the equilibrium of the main support in a liquid space ( ), it is regulated by the filling or emptying of a box - waterproof ballast (1) - which has the function of balancing the device as a whole when stopped and running. For the establishment of the production unit on its site and contain the reaction forces, a set of cabling (3) will allow its mooring including a provision allowing, if necessary, to follow the fluctuations in the level of the surface of the liquid space. The cables fixed at the bottom by suitable bases, tie rods and seals, must be able to contain the reaction movements of the main support subjected to the operation of the chain, when stopping or restarting. The adjustment of the chain tension will be carried out by a mechanical system based on cylinders allowing the lengthening or shortening of the main vertical column connecting the 2 chain support drums.

The geometric shape of the cylindrical envelopes topped with two hemispherical shells avoids any uneven shape which is a source of wear or hydraulic turbulence. The rounded geometric shapes best suited for folding and opening the ECVV provide the lowest possible hydrodynamic drag in all sections of the chain rotation cycle.

Envelopes ( ) are each subject to two BLAR devices which are diametrically opposed and which surround them on either side; this positioning requires a particular arrangement of the BLAR devices in relation to neighboring units and vice versa to avoid collision. The main axis common to the 2 symmetrical BLARs crosses the median plane of the envelope, this axis is fixed to the base by bars (27). These fixed arms and the axis determine a fixed plane secured to the base. ( ). It is from this fixed plane that the two BLAR systems develop or retract simultaneously, driving the envelope they enclose.

Then, the 2 axial axes (18) of the BLAR ( ) extend through the top and bottom of the envelope forming 2 cylindrical spaces (open to each other) and similarly pass through the other BLAR device.

An offset (E) - see - due to the elongation of the axes of the envelope on its side near the base, which makes it possible to locate one of the BLAR devices further away giving the possibility of the end of the BLAR passing through the space of the neighboring unit of the chain without hindering the operation of similar elements of this unit thus flown over. The following 4 elements of the BLAR have no action other than the operation of the BLAR, according to the actions produced symmetrically by the two moving masses of the 2 BLARs serving the same envelope. The BLAR system ( ) is formed of a series of virtual volumes (28) forming a line of rhombohedra which have in common the axial bars which make two neighboring virtual volumes adjoining. The entire series of volumes described is enclosed and guided between two sliding rails (23). These are joined together at 3 points: At the level of the first fixed bar (19), by a crosspiece (24) then at mid-length by an easel (25) and at the end (near the moving mass) by a another crosspiece (26). The guide rail chassis is fixed to the base by the reinforcement hoop of the ECVV envelope itself joined to the base by the By-pass structure (14). The middle part of the frame-rail is linked to the other end of the base by two bars (27).

Bearing pads (31) ( ) fixed to the ball joints of the axial bars (16 and 18) move freely inside these guide rails (hollow profiles). Only the fixed main axial bar (19) does not have a bearing.

The bridge (25) will maintain a regular spacing between the elements of the frame to take into account the different forces varying in intensity and direction during the cycle of the chain. In this regard, we note that the rolling pad (31) has a dimension smaller than its movement frame which allows it to roll on one side or the other according to the different variations in force and direction implied by the movements of the mobile mass to all the elements of the BLAR device.

The last axial bar of the BLAR system supports a mobile mass (9) which, through its movements, ensures the development and retraction of the BLAR device.

It is supported on 2X2 pads located in the rail chassis.

This guide rail chassis (23) will be shaped with special profiles joined by continuous welding.

The deployment and folding of an envelope are controlled by the actions of two BLAR devices, which for their operation are dependent on the movements of mobile masses according to the orientations of the latter to the gravitational field during the cycle of the chain. The direction and force of their action therefore constantly change, causing the envelopes to unfold and fold one after the other. These actions are supported by two BLAR lever arm devices which enclose the envelope. The penultimate rhombohedral element (33) which is opposite the mobile mass directly activates the opening and closing of one of the half spaces of the envelope, the other half space is served by the last element (34) which is the mirror of the element (33) its twin; this second element is symmetrically mounted relative to the central axial bar (19) which is the fulcrum of the BLAR. The force produced symmetrically by the two BLARs and for each by their two paired elements leads to a simultaneous action for the opening or closing of the entire envelope. This assembly promotes good balance of the casing and contributes to that of the chain.

The bases connected together by the connectors (8) form the chain, but the purpose of these connections is to participate in forming a sheath and not to be a mechanical link, this function is in fact provided by coupling parts ( 21) located and fixed on either side of the ends of the bases. At their ends, they are assembled together by means of a ball joint (22) which allows them to articulate together in the same plane. These assemblies play a vital role in structuring the chain and contributing to its good balance. Let's consider the mechanical line, it must pass through the centers of gravity of the links (base + envelope + the 2 lever arms and their mobile mass). The position of the centers of gravity of the links of the rising column is different from that of the descending column, this is essentially due to the positions of the moving masses. Note that the line of the mechanical link passes through the bases, so to maintain a good balance in the chain and prevent it from having a tendency to seize and therefore lose production and be open to rapid wear, it is necessary to limit the amplitude of the rotation of the ball joint (22). For this purpose, the coupling parts (21) joined by the ball joint can form a projecting angle towards the outside when they pass over the drums, but on the other hand must not have the same possibility towards the inside of the chain ; because it is the free position that the coupling parts would take having regard to the various off-center efforts of the centers of gravity.

The pressure of the gas contained in the hyperbaric circuit will change during operation (according to the laws of gas physics) depending on meteorological variations acting on the ambient temperatures between the bottom of the liquid space and its surface. An onboard compressor-decompressor device (located between two bases) will have a dual function:

1) Manage the continuity of the internal average pressure of the hyperbaric circuit according to variations in environmental temperatures.

2) Maintain the pressure and the security of the network in terms of its tightness. Communication with the control center will make it possible to monitor the correct activity of the different units in particular. This compressor will only capture the energy necessary for its own operation when it benefits from an electrical induction located on the path of the chain.

The operating principle of the GEiCG process having been described, various provisions allowing its implementation are presented:

First of all, in terms of studies, various equations put into calculation centers concerning the operation of this device have each produced positive results. On a practical level, let's imagine the following experiment: a prototype has been built, the air in the duct and the envelopes are naturally at a pressure approximately equal to atmospheric pressure. The device is positioned vertically, the moving masses of the descent phase compress the envelopes and the hemispherical shells come together. On the other hand, the moving masses of the rising phase stretched the BLAR devices. Then air is sent into the sheath, until a pressure somewhat higher than atmospheric pressure is reached, which allows the envelopes to be opened widely. Let’s then immerse the entire device in water. To activate it, simply blow air into the duct until the average hydrostatic pressure necessary is reached so that the device automatically starts continuous operation.

The description of the operation of the chain is considered in relation to a stable and fixed support. Let us therefore examine what contributes to the balance of the main support, floating and carrying the device, ( ) it is regulated by the filling or emptying of the box (1) - waterproof ballast - which has the function of balancing the device as a whole when stopped and running. To secure the production unit in its site and contain the reaction forces, a set of cabling (3) will allow its mooring including, if necessary, a provision making it possible to follow the fluctuations in the surface level of the liquid space . The cables are fixed at the bottom by suitable bases, tie rods and seals, they must be able to contain the reaction movements of the main support subjected to the operation of the chain, when stopping or restarting. Above the ballast box (1), we find the technical room (2) easily accessible through a hatch close to the maintenance dock.

The prototype tests will make it possible to calibrate the common unit weight of the mobile masses with regard to the length of the BLAR devices which frame the ECVV. It is interesting with regard to hydrodynamics that the BLAR is not too long longer than the double height of an ECVV. This arrangement, through the adoption of the double BLAR equipment which frames the envelopes, ensures good balancing corresponding to good performance limiting drag and friction.

Concerning maintenance, after a certain number of years of operation in the maritime zone, each unit will be towed to an appropriate site for an inspection and general overhaul. A complete standard exchange of the constituent elements of the chain will be carried out. Regarding routine maintenance of the GEiCG device: Following an incident and for a fixed period to be determined, maintenance will most often consist of only the standard exchange of a cell (base + ECVV + BLAR) or a connection, sensitive elements in relation to the other constituent elements of the GEiCG device. It will be necessary to stop the chain, a “blocking stop” with the base concerned being stopped at the maintenance dock.

The two bases adjacent to the defective base will be blocked on either side of the stopping section opposite the maintenance dock which is provided for dismantling the unit in question; stopping on the drum will hold the rest of the chain. This will remain in place while awaiting the assembly of the new unit. This provision will in principle allow an automatic restart.

The obviously necessary maintenance will be relatively expensive compared to other methods of energy production, since it is not dependent on high technicality.

For the realization of GEiCG, we are interested in its insertion into the natural environment and the industrial world. Let us begin with a remark concerning this device which, at first glance, surprises many scientific minds, such as the following statement:

“Its only resource is exclusively free and permanent - Gravitational Force - without having to confiscate any terrestrial space”.

The scientific principles are demonstrated on simple elements without interference and they remind us that we cannot produce more energy in a device than the quantity originally put in (whatever its form). Several actions taken separately each respond to the laws of physics that concern them. So a logical mind will conclude mathematically that: 0+0+0 is always equal to zero. But here, with regard to the GEiCG, we are in a combination of different actions which respond to several scientific laws which coordinate and help each other by using a natural force in various actions: the gravitational field. We are precisely in a systemic functioning (the best example closest to us is our own body, all the elements of which are united and dependent on each other).

The GEiCG device outside the gravitational field has only one need: aquatic exploitation sites, seas and oceans, large lakes, these cover 70% of the surface of the globe; but the great depths limit the surface area of easily exploitable sites to 7 to 10%. Unlike most other electrical energy production processes, this device does not use any carbon or nuclear resources, etc.

Each new energy has various disadvantages and the GEiCG system is no exception; it was criticized for numerous frictions following its first presentation. Therefore, various modifications were made, in particular a simplification of the chain seats replaced by an adapted adjustment of the spacing between the two carrying drums in order to obtain adequate tension of the chain.

The device is only presented here individually, in industrial reality this element will belong to a set whose importance of the number of units will depend on the desired power. The units will be arranged in a configuration where they are aligned and secured together all served by the HT cable and the monitoring and control cables.

The units will be built separately and distributed worldwide transported or moved by water wherever clean and non-polluting energy needs are expected. The units can be built on developed sites or in shipyards. From these locations, the GEiCG device will be quite easily towed by sea for installation at its operating site. Thus these energy generators built in one point of the globe could have a point of use located on the other side of the planet. We can expect that improvements will gradually be made allowing more mobile units to be produced and whose power will increase through the use of materials allowing the use of higher pressures.

Less easy, implementation in deep lakes will require construction by assembly of spare parts delivered and assembled on the operating site. Other features to consider: Several units can be assembled and coupled to form a deep draft vessel. This equipment can provide energy support required by an exceptional event or to relay a production site forced to shut down. A similar service can be programmed with a view to participating in strengthening the power supply of a territory's network in order to respond to a particular context: cataclysm....etc. It would be a super high-power floating generator, with a non-carbon energy source. The movement of marine vessels and floating generators would take place with all production lines stopped and cells folded. The hydrostatic balance of the whole being different during transport - operation stopped - an airlock system similar to that of a submarine will make it possible to balance the super generator according to its activity. This would also be equipped with drums intended to receive the cable line to ensure all or part of the connection with the coast or the site concerned.

The operation of this system may contribute to the development of maritime natural heritage; among its many possible applications, it can ensure the energy independence of small islands and island regions. This new equipment will make it possible to serve isolated territories or will be integrated into a set established as a “farm” allowing the grouping of various productions concentrated in a region or a maritime area.

A set established on a “farm” could include wind turbines and tidal turbines attached to or connected to the units of the device presented here.

Let us add that in the event of an earthquake, the maritime farm would be more secure than a hydroelectric dam on land or any other coastal facility. Future attention will also be focused on these dams, most of them built in the middle of the 20th century, which are aging and concentrate various ecological hazards; for safety reasons, their demolition would seem to be planned in the long term.

From the economic, rational aspect, unlike other types of energy production participating in the energy transition, the system presented is a continuous and regular production base. Note that during off-peak hours, energy not transmitted on the general network can be used to meet various activities and needs:

• In a seawater desalination unit, coupled with pumping of the fresh water produced towards distribution network reserves or towards areas to be irrigated. In addition to producing electricity, this process will make it possible to bring water to those who are most deprived.
• In industrial chemical needs: To supply industrial electrolysis plants to “crack” water for the manufacture of tomorrow’s hydrogen-based fuels with a very low CO2 content.
• By avoiding monocultures to produce biofuels and the tendencies to unbalance subsistence agriculture in developing countries.

- By producing the electrical energy necessary for the production of aluminum...etc.

• As an electrical energy storage station in future installations to come.

Thus this device can largely contribute to the energy transition, particularly in the transition from the carbon-based era to a new, less carbon-based one to come.

As part of the development of maritime heritage, on an ecological level with regard to plankton and krill, living matter and basic food for various marine species, studies have shown that it is the currents which mix the waters from the bottom to the surface and vice versa, which favor the generation of this living matter. The operation of the GEiCG device can only be a favorable factor in the type of water mixing that it implies through its operation. As for aquatic fauna, warned by the transmission of sound effects or vibrations, they will move away from the site as a natural precaution. As for navigation, the advantage of the GEiCG device operating in total immersion makes it possible to locate its top at the coast of - 15/20 meters if necessary to escape the drafts of larger ships.

The device presented here individually is in reality only one element belonging to a set whose importance of the number of units depends on the desired power. The units will usually be arranged in a configuration where they are aligned and secured together, all served by the HV cable transporting production to the coast.

Let's leave maritime environments to approach large towns near which there are often old sand quarries still submerged by the nearby presence of a watercourse. The use of such sites represents interesting potential. Other sites, such as hydroelectric dams (for those that will be maintained), have large, deep lakes and are already served by transmission lines; these sites can be developed by providing significant reinforcement using equipment made up of several units. The system would be able to meet demand during off-peak hours and also to accumulate and allow a strengthening of the dam's production during peak hours.

The excess energy generated by the GEiCG device will allow the recovery and transformation of materials to save our natural resources. Furthermore, many tire recycling centers must be operated to protect the environment. There is an interesting source there for the creation of different elements of the ECVV of the present system

We must get used to the idea that it will not only not be possible to reduce demand, but also to stem the growth in energy demand. In 25 years, the consumption of electrical energy demand will have increased according to experts by 40 to 70%.

Concerning agriculture, faced with the lack of cultivable areas, many spaces which are unused today will become really necessary in the future. Those, where the rock is exposed, can be crushed on the surface with the same crushing techniques as those currently used for replacing road surfaces. The rock dust will be mixed with dust from garden or household waste, to create and reach new cultivation land.

Energy saving policies will never be able to respond to the unanimous desire to obtain a gradual elimination of energy production by carbon or nuclear methods. Large consumers of lighting, heating, air conditioning and transport will appear, as will large-scale hydrogen production; but also it will be necessary to increase above-ground crops which will undoubtedly see significant growth in the face of the increase in the population in certain countries and the undernourishment of a large part of the inhabitants of the Third World. Units of the GEiCG system can be built and distributed throughout the world and also transported or moved by sea wherever clean and non-polluting energy needs are expected. Thus these generators built in one point of the globe can be delivered to an operating site located on the other side of the planet.

For its operation, GEiCG uses exclusively the gravitational field as well as the atmosphere and liquid spaces, the latter covering 4/5 of the surface of the globe. This device will help prevent the proliferation of wind turbines which clutter, or even spoil, our landscapes. Moreover, their implementation is becoming more and more difficult to achieve in many respects. We must also consider the removal of land confiscated by photovoltaics to the detriment of agriculture or reforestation.

It is important for many regions of the world to acquire new energy production potential, without resorting to the diffusion of nuclear techniques and the questionable dissemination of spent fuels. We must always anticipate the growth in the mechanization of activities of all kinds, means of transport for the movement of goods and people, a growing number of electric vehicles. The building will become more and more consuming through the development of electric heating, but also air conditioning in the face of global warming, as well as the persistence of an expectation of better comfort in the home with the generalization of VMC which generates large losses of calories.

The device presented here is not subject to the vagaries of clouds and winds, it is practically independent of climatic conditions, without having to resort to the natural resources of the planet, to the geological particularities which contribute to creating inequalities with regard to the wealth of basements. Improvements and transformations will be made to this device and other processes will also be initiated, with a view to better promoting the field of exploitation of the gravitational field, which is a continuous, free and perpetual resource before which men are equal. , an identical resource for everyone, in all regions of the globe, both polar and equatorial zones. It is a particularly interesting source of energy because it is regular and inexhaustible.

The exploitation of the gravitational field, without being subject to the vagaries of wind intensity, sunshine or rainfall, is completely part of the energy transition to participate in the establishment with the greatest number of nations

(195 countries) to this transition initiated by the Paris Agreement - December 12, 2015.

Claims (5)

1 - Device generating electrical or mechanical energy using the gravitational field in systemic operation, characterized in that it is formed of a slender vertical support (1) around which a chain closed on itself winds vertically resting on drums (5), the assembly being largely submerged, the links are parallelepiped hollow elements connected together by metal couplings (21) which frame flexible connections (8) the latter make it possible to make them communicating with each other, in order to form a continuous sheath throughout the chain, these hollow elements each function as a hollow base (6) opening via a by-pass (14) to a flexible envelope (7) of cylindrical shape and hemispherical, these retractable and waterproof envelopes are in communication with each other, these deployed each form a gaseous space of constant average pressure and volume, each envelope is enclosed in a particular arrangement between two retractable lever arm systems mounted in scissors, thus secured at its two devices it undergoes at 4 points the efforts for deployment or folding simultaneously with these which themselves receive the product in force and direction of the movements of the mobile mass (9) according to the reactions of the latter due to its changes of exposure to the gravitational field having the consequence of deploying the envelopes on one side and closing the same on the other side during the rotation of the chain which is produced by the effect of the Archimedes thrust exerted on the column of envelopes which are developed unlike the folded envelopes of the column on the other side of the chain support. 2 - Device according to claim 1 concerning the positioning and tension of the chain which is characterized in that it is installed on a vertical support carrying a drum in the upper part and another in the lower part of the device, their spacing is adjustable by a cylinder mechanism located near the axis of the upper drum, the bases constituting the chain are supported on the drums via neoprene plates, the energy carried by the chain is transmitted via the upper drum by gears and gears to the receiving device. 3 - Device according to claim 1 concerning the geometric shape of the envelopes which is characterized in that their cylindrical shape topped with two hemispherical shells avoids any angular shape which is a source of wear or hydraulic swirls, the rounded geometric shapes more suitable for folding and The opening of the ECVV provides the lowest possible hydrodynamic drag in all sections of the chain rotation cycle. 4 - Device according to claim 1 characterized in that the envelopes (figure 1) are each subject to two BLAR devices which are diametrically opposed and which enclose them on either side, this positioning requires a particular arrangement of the BLAR devices by in relation to neighboring units and vice versa to avoid their collision, the devices are symmetrically offset with those of neighboring envelopes in relation to the axis of the chain, in addition an offset (E) - see figures 3 and 5 - is produced by the elongation of the interior axis, furthest from the envelope, which makes it possible to locate one of the two BLAR devices further apart allowing the intrusion of the end of this BLAR into the space of the unit neighboring the chain without hindering the operation of similar elements of this unit flown over. 5 - Device, according to claims 1 and 4, which is dependent for its operation on the movements of mobile masses depending on their orientation to the gravitational field during the cycle of the chain, the direction and force of their action change permanently causing the unfolding and folding of the envelopes to follow one another, these actions are characterized in that the operation of deployment and closing of an envelope is carried out by two BLAR lever arm devices which enclose the envelope, the penultimate rhombohedral element ( 33) which is opposite the mobile mass directly activates the opening and closing of one of the half spaces of the envelope, the other half space is served by the last element (34) which is the mirror of the element (33), this second element is symmetrically mounted relative to the central axial bar (19) which is the fulcrum of the BLAR, by this assembly the force produced symmetrically by the two BLARs is equally distributed between these two elements paired in a simultaneous action in opening or closing of the entire envelope served by the two BLARs considered.