WO2018138141A1 - Aero-hydraulic motor system - Google Patents

Abstract

The application relates to an aero-hydraulic motor device (100; 200; 300; 400), comprising a reservoir that is referred to as the upper reservoir (102) and is designed to receive a liquid, referred to as the working liquid (108); a reservoir that is referred to as the lower reservoir (104), is designed to receive said working liquid (108) and is arranged below the level of said upper reservoir (102); a reservoir that is referred to as the central reservoir (106), is designed to receive said working liquid (108) and is arranged in/on said lower reservoir (104), said central reservoir (106) comprising a duct, referred to as the central duct (124), connecting said central reservoir (106) to said upper reservoir (102); at least two pistons (112₁-112₂), each being arranged so as to be able to move in translation in a cylinder referred to as a lateral cylinder (110₁-110₂), said lateral cylinders (110₁-110₂) being positioned: • on either side of said central reservoir (106) and connected to said central reservoir (106), • in/on the lower reservoir (104) and connected to said lower reservoir (104), • below said upper reservoir (102) and connected to said upper reservoir (102); and a connecting rod-crank device (142) which is rigidly connected to at least one and in particular both pistons (112₁-112₂) and is designed to be driven in rotation by said pistons (112₁-112₂); characterized in that: -each piston (112₁-112₂) is driven in translation in its lateral cylinder (110₁-110₂) downward by the working liquid emptying from the upper reservoir (102), and -said piston (112₁-112₂) drives the other piston upward and the rotation of said connecting rod-crank device (142).

Description

 "Aero-hydraulic motor system"

The invention relates to an aero-hydraulic motor system. The field of the invention is the field of energy production systems, in particular aero-hydraulic motor systems.

STATE OF THE ART

 We know the energy production systems from hydropower such as hydroelectric power stations, tidal, or tidal turbines. These systems use the kinetic energy of waterfalls or ocean currents to produce electrical energy. However, these systems are complex to achieve and expensive. In addition, these systems depend on weather conditions and in particular the energy value of water. Such systems are as complex and expensive to maintain.

An object of the present invention is to overcome these disadvantages.

Another object of the present invention is to provide an aero-hydraulic motor system simpler to maintain in comparison with systems of the state of the art.

 Another object of the present invention is to provide an aero-hydraulic motor system independent of the meteorological conditions in comparison with the systems of the state of the art.

 Another object of the present invention is to provide a less expensive aero-hydraulic motor system.

 Another object of the present invention is to provide an aero-hydraulic motor system simpler to perform in comparison with systems of the state of the art.

SUMMARY OF THE INVENTION

At least one of the aforementioned objects is achieved by an air-hydraulic motor system, comprising: - a reservoir, said superior, intended to receive a liquid, said work;

 - A reservoir, said lower, adapted to receive said working liquid, and arranged below the level of said upper reservoir;

 a so-called central reservoir designed to receive said working liquid and arranged in / on said lower reservoir, said central reservoir comprising a so-called central duct connecting said central reservoir to said upper reservoir;

 at least two pistons, each arranged movable in translation in a cylinder, said lateral, said lateral cylinders being positioned:

 • on both sides of said central tank and connected to said central tank,

 In / on the lower reservoir and connected to said lower reservoir,

Under said upper reservoir and connected to said upper reservoir; a crank-rod device rigidly connected to at least one, in particular to the two pistons, designed to be rotated alternately by said pistons;

characterized in that

 each piston is driven in translation in its side cylinder downwards by the working liquid flowing from the upper reservoir, and

 said piston drives the other piston upwards and the rotation of said crank-rod device.

With the system according to the invention, the working liquid present in the upper reservoir is operated, by the effect of gravity on one of the pistons, to cause the rotation of the crank-crank device. The crank-rod device thus produces, from the displacement of the working fluid, mechanical energy that can be, if necessary, converted into electrical energy and / or used in a hoist system or an elevator. The system according to the invention is therefore simple to implement and less expensive to produce. In addition, the system according to the invention has a reduced size compared to the systems of the state of the art. Preferably, the lateral cylinders are identical. The volume of the working liquid pumped by each side cylinder is thus identical.

In one embodiment of the system according to the invention, each piston can be driven in translation in its cylinder downwards, to a predetermined position, so that said piston can transfer working liquid, previously admitted in said cylinder from the lower reservoir, to said central reservoir thus causing the transfer of said liquid from the central reservoir to the upper reservoir, and when said piston reaches said predetermined position, it can release an opening in said lateral cylinder allowing the evacuation of the working liquid from discharging into said side cylinder to the lower tank, thereby causing the transfer of the working liquid present in said lower tank into the other side cylinder.

 Thus, each side piston can be used to transfer the working liquid admitted into the side cylinder to the upper reservoir for reuse to induce rotation of the crank-connecting device. The system according to the invention therefore requires less working fluid to produce energy and is easier to maintain. In an embodiment, the system according to the invention may comprise, for each lateral cylinder, a conduit, said upper, connecting the upper reservoir to said side cylinder and allowing the transfer of the working liquid from the upper reservoir to said cylinder.

 The diameter of at least one upper duct may be less than the diameter of at least one side cylinder.

In particular, the diameter of at least one upper duct may be between 1 cm and 50 cm, in particular equal to 5 cm, and in this the height of at least one upper duct may be between 0.5 m and 50 m , in particular equal to 5 m.

The pressure of the working liquid discharging from the upper reservoir into the side cylinder increases with the height of the upper conduit, thereby allowing the displacement of the piston and the rotation of the crank-crank device. For example, for an upper duct with a diameter of 2 cm and a height of 5 m and a volume of working fluid of 1.57 I, the pressure of the liquid at the outlet of the duct is increased by a factor of 5. Alternatively, the height of at least one upper duct may be greater than 50 m.

In particular, the position of the upper reservoir can be adjustable. In addition, the height of the upper duct and the level of the working fluid in said upper duct can be adjustable, to adjust the pressure and the speed of the working liquid.

The diameter of the central duct may be smaller than the diameter of the upper duct.

According to the invention, the connecting rod-crank device can be arranged under the upper reservoir. Alternatively, the crank-rod device can be disposed above or below the lower tank.

In an embodiment of the system according to the invention, at least one turbine may be positioned so as to be driven by the working fluid transferred from the central reservoir to the upper reservoir, in particular said turbine may be positioned at the outlet of the central duct.

 The turbine can be used to produce electrical energy. The working fluid flowing from the central duct during its pumping induces the movement of the turbine and thus the production of electrical energy by said turbine.

Advantageously, the system according to the invention may comprise a battery for storing the electrical energy produced by the at least one turbine and / or the crank-rod device. In an advantageous embodiment of the system according to the invention, each side cylinder may comprise a check valve, said lower, arranged on the bottom wall of said side cylinder and overlooking the lower reservoir, and provided to allow the passage of the liquid working from the lower reservoir to said side cylinder.

 In particular, each lower valve may be a synchronized opening check valve, in particular with the movement of the pistons.

 The position of at least one lower valve can be adjustable.

In an embodiment of the system according to the invention, the upper reservoir may comprise two so-called upper check valves, each one giving onto a lateral cylinder, and provided to allow the passage of the working liquid from the upper reservoir to said cylinder .

 In particular, each upper valve may be a synchronized opening check valve, in particular with the movement of the pistons.

 The position of at least one upper valve can be adjustable.

Advantageously, the opening of the lower valve of a lateral cylinder and the upper valve facing the other lateral cylinder may be simultaneous.

According to an advantageous embodiment of the system according to the invention, the connecting rod-crank device can be connected to the upper valves to trigger alternately the opening or closing of one of said upper valves.

Preferably, the system according to the invention may comprise, for each lateral cylinder, a so-called lateral duct connecting said cylinder to the central tank and comprising a so-called lateral check valve intended to allow the passage of the working fluid from said cylinder to the central tank.

In particular, the diameter of the lateral ducts may be smaller than the diameter of the lateral cylinders. The working liquid is transferred into the central tank with a high pressure thus allowing its pumping. The central tank may have a height less than or equal to three quarters of the height of the central duct.

The system according to the invention may comprise, for each lateral cylinder, a duct connecting the lower wall of said cylinder to the upper reservoir. Said duct may comprise an anti-return valve.

 The conduit and the valve may be configured to transfer the working fluid from the upper reservoir to the lower portion of said cylinder to drive the piston into said cylinder upwardly. This arrangement makes it possible to apply additional pressure to drive the piston upwards.

Each side valve can be a synchronized opening check valve.

 The position of at least one lateral flap can be adjustable.

The opening of the lateral valve of a lateral duct and the upper valve of the lateral cylinder connected to said lateral duct may be simultaneous.

Alternatively, each side cylinder may comprise a nonreturn valve arranged on one side of said cylinder at its lower part and facing the lateral duct.

Advantageously, each side cylinder may comprise at least one orifice arranged on one side of said lateral cylinder, intended for the admission, and possibly the evacuation, of air in said cylinder.

 The air intake ports may be arranged at mid-height of said side cylinder.

 In addition, the air intake ports may be arranged below the end of stroke of the piston in said cylinder.

In addition, each side cylinder may comprise at least one inlet valve, and possibly exhaust valve, air arranged on the upper part of said side cylinder. In particular, each side cylinder may comprise two valves arranged on either side of the upper duct giving onto said lateral cylinder. In a preferred embodiment, the system according to the invention may comprise, for each lateral cylinder, a duct, called evacuation, connecting the opening of said cylinder to the lower reservoir and allowing the transfer of the working fluid from said cylinder to the lower tank. In an advantageous embodiment, the system according to the invention may comprise at least one duct, called air duct, connecting an upper duct to the central duct, designed to transfer air from the upper duct to said central duct.

 When a piston of a side cylinder is driven towards the upper conduit, the air in said cylinder is compressed. The air duct makes it possible to direct the compressed air towards the central duct and to induce the pumping of the liquid by air injection (Airlift in English). Pumping the liquid is thus more efficient. In addition, the system according to the invention may comprise two air ducts.

 Each of said air ducts may connect an upper duct to the central duct. Thus, the pumping of the working liquid can be carried out by air injection in a continuous manner.

Advantageously, at least one turbine can be arranged in at least one air duct.

 The electrical energy can be produced in this case by the passage of air in the turbine.

In an embodiment of the system according to the invention, each upper duct may comprise an intake opening and / or air outlet. According to an embodiment, the system according to the invention may comprise, for at least one cylinder, an air tank, arranged in said cylinder under the piston of said cylinder.

 The air tanks, by Archimedes thrust, reduce the energy required to drive one of the pistons upwards at the end of the piston travel down.

Preferably, the system according to the invention may comprise a second connecting-rod device connected to the lower valves and arranged to be driven by the alternative opening or closing of said lower valves.

In particular, the system according to the invention may comprise a first air compression device comprising:

 a first cylinder comprising a first piston connected to a lower valve,

 a second cylinder comprising a second piston connected to the other lower valve, and

 an air duct connecting said cylinders to each other and to the central duct. The opening or closure of a lower valve causes the displacement of a piston upwards or downwards, and thus the admission of air into a cylinder, respectively the compression of air by a piston. .

 The first air compression device thus makes it possible to inject air into the central duct, in order to contribute to the pumping of the working liquid by air injection.

 Preferably, at least one turbine may be arranged in the air duct. According to one embodiment, the system according to the invention may comprise a second air compression device comprising:

 two pistons, each of said pistons being connected to a lateral valve, two cylinders each comprising one of said pistons, and

an air duct connecting said cylinders and to the central duct. The compressed air produced by the second compression device is directed towards the central duct and participates in pumping by air injection.

 In particular, at least one turbine can be arranged in the air duct.

Alternatively, or in addition, the central duct may be at least partly deformable and may comprise at least one non-return valve.

 Thus, the working liquid can be transferred to the upper reservoir by using the deformations of the central duct due to the pressure in the central reservoir.

 The central duct may comprise a plurality of nonreturn valves distributed along said central duct.

Advantageously, the system according to the invention can be integrated into a vehicle, such as a train, a bicycle, etc., and arranged to induce the movement of said vehicle.

 In particular, the connecting rod-crank device can be connected to at least one wheel of said vehicle. Advantageously, the system according to the invention can be integrated in a hoist device.

DESCRIPTION OF THE FIGURES AND EMBODIMENTS

 Other advantages and characteristics will appear on examining the detailed description of non-limitative examples, and the appended drawings in which:

 FIG. 1 is a schematic representation of a first example of the system according to the invention;

 FIG. 2 is a schematic representation of a second example of the system according to the invention;

FIG. 3 is a schematic representation of a third example of the system according to the invention; and FIG. 4 is a schematic representation of a fourth example of the system according to the invention

 It is understood that the embodiments which will be described in the following are in no way limiting. It will be possible, in particular, to imagine variants of the invention comprising only a selection of characteristics described subsequently isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the art. This selection comprises at least one feature preferably functional without structural detail, or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art.

 In particular, all the variants and all the embodiments described are combinable with each other if nothing stands in the way of this combination at the technical level.

 In the figures, the elements common to several figures retain the same reference.

FIGURE 1 is a schematic representation of a first example of the system according to the invention.

 The system 100 of FIGURE 1 comprises a tank, said upper 102, and a tank, said lower 104, arranged under the level of the upper tank 102. The system 100 comprises a so-called central tank 106, arranged semi-immersed in the lower tank 104. The upper tanks 102, lower 104 and central 106 can each receive a working liquid 108.

The system further comprises two cylinders, called lateral cylinders IO1-I IO2, arranged on either side of the central reservoir 106, and are partially immersed in the lower reservoir 104. Each cylinder IOI-I IO2 comprises a respectively 112ι piston -112 ₂ .

In addition, the system 100 comprises two ducts, said upper 114-114 ₂ , respectively connecting the cylinders 110i-110 ₂ to the upper reservoir 102. The upper reservoir 102 comprises two valves, said superior I61-I I62, anti-return arranged above each upper duct respectively 114ι-114 ₂ . The upper valves 116 open alternately allowing the flow of the liquid 108 in one of the cylinders 110, and thus the drive of one of the pistons 112.

 Furthermore, each piston 112 is connected to a crank-rod device 142. The displacement of each piston 112 causes the rotation of the crank-rod device 142. The crank-rod device 142 is arranged under the upper reservoir. In addition, the crank-rod device 142 may be connected to a means, not shown in FIG. 1, for producing electrical energy from kinetic energy.

The cylinders 110i-110 ₂ respectively comprise valves, said lower 118i-118 ₂ arranged on a lower base of said cylinders 110-110 ₂ and overlooking the lower tank 104. The lower valves 118 are synchronously opening and alternating allowing the passage of the working fluid 108 from the lower reservoir 104 to one of the cylinders 110.

The system 100 comprises two lateral ducts 120i-120 ₂ , respectively connecting the cylinders 110i-110 ₂ to the central tank 106. Each of the lateral ducts 120i-120 ₂ comprises a check valve, said lateral, respectively 122i-122 ₂ . The opening of the valve 122I, respectively 122 _2, allows the passage of working fluid 108 from the lateral cylinder 110i or 110 _2, the central reservoir 106.

The valves 116 ₂ , 118i and 122 ₂ are simultaneously in the open position, while the valves 116i, 118 ₂ and 122i are in the closed position and vice versa.

The system 100 also includes a conduit, said central 124, connecting the central reservoir 106 to upper reservoir 102. In addition, two 126i- 126 _two turbines are arranged to the outputs, the central duct 124.

Each lateral cylinder 110i-110 ₂ comprises a duct, said discharge, respectively 128i-128 ₂ comprising a check valve 130i-130 ₂ . The valve 130 of the evacuation duct 128 allows the evacuation of the working liquid 108 from the upper chamber to the piston 112 of the cylinder 110 towards the lower reservoir 104.

When the upper valve 116 ₂ is in the open position, the working liquid 108 flows into the side cylinder 110 ₂ through the upper conduit 114 ₂ , driving the piston 110 ₂ in a direction 132. The displacement of the piston 112 ₂ causes the working liquid 108 to move in a direction 134 towards the central reservoir 106 and its pumping to the upper reservoir 102 through the central conduit 124 in a direction 136. When the piston 112 ₂ exceeds the level of the conduit of FIG. evacuation, the valve 130 ₂ is placed in the open position, the working liquid 108 is discharged in a direction 138 in the lower reservoir. The excess working liquid 108 causes the piston 112i to move by filling the cylinder 110i in a direction 140. The working liquid 108 is pumped symmetrically when the upper valve 116i is in the open position.

The FIGU RE 2 is a schematic representation of a second example of the system according to the invention.

The system 200 of FIG. 2 comprises the same elements as the system 100 of FIGU RE 1. In addition, the system 200 comprises two ducts, called air ducts, 204i and 204 ₂ each connecting the upper duct 114i, respectively 114 ₂ in the central duct 124. In addition, the upper ducts 114i-114 ₂ comprise air intake orifices 206i-206 _{2 respectively} . When the piston 112 is driven in the direction 132, the air inlet 206 is open and allows the admission of air into the upper conduit 114. When the piston 112 is driven in the direction 140, the air inlet port 206 is closed. The previously admitted air is thus sent back to the central duct 124 through the air duct 204. The pumping efficiency of the liquid 108 is thus improved by injection of air.

 In addition, the air ducts 204 comprise turbines 126 for transforming the movement of the air in the air duct 204 into electrical energy.

In particular, the cylinders IO1-I IO2 comprise air inlets respectively 208i and 208 ₂ . When the piston 112 is driven in the direction 132, the air is admitted into the cylinder 110 through the orifice 208. When 112 is driven in the direction 140, the air previously admitted into the cylinder 110 is pushed towards the upper duct 114.

In addition, the crank-connecting device 142 is connected to the upper valves 116 and cause their opening / closing by its rotation. FIGURE 3 is a schematic representation of a third example of the system according to the invention.

The system 300 of FIGURE 3 comprises the same elements as the system 200 of FIGURE 2. In addition, the system 300 comprises two air reservoirs 302i-302 ₂ arranged under the pistons respectively 112i-112 ₂ .

 The air tanks 302 contribute to the displacement of the pistons 112 by the buoyancy of Archimedes.

 For example, the air tanks 302 may be air pockets.

FIGURE 4 is a schematic representation of a fourth example of the system according to the invention.

The system 400 of FIGURE 4 comprises the same elements as the system 200 of FIGURE 2. The system 400 comprises an air compression device 402. The air compression device 402 comprises two cylinders 404i-404 ₂ respectively comprising two pistons 406i-406 ₂ . The 406i-406 _two pistons are connected to the lower valves 118i-118 ₂ respectively. In addition, the cylinders 404i-404 ₂ are interconnected to the central duct 124 by a duct 408. The duct 408 also allows the admission of air to the cylinders

404i-404 ₂ by valves 410i-410 ₂ .

When the lower valve 118 ₂ , respectively 118i, closes, the piston

406 ₂ , respectively 406i, is driven downward thus compressing the air present in the cylinder 404 ₂ , respectively 404i. The compressed air is conveyed to the central duct 124 through the duct 408 and participates in pumping by air injection.

 In particular, a turbine 126 is arranged in the conduit 408 to produce electrical energy.

Of course, the invention is not limited to the examples that have just been described and many adjustments can be made to these examples without departing from the scope of the invention.

Claims

A device (100; 200; 300; 400) aerohydraulic engine comprising:  a reservoir, said upper (102), designed to receive a liquid, said working (108);  - a reservoir, said lower (104), adapted to receive said working liquid (108), and arranged below the level of said upper reservoir (102);  a reservoir, said central (106), designed to receive said working liquid (108) and arranged in / on said lower reservoir (104), said central reservoir (106) comprising a conduit, said central (124), connecting said central tank (106) to said upper tank (102); - At least two pistons (112ι-112 ₂ ), each arranged movable in translation in a cylinder, said side (110i-110 ₂ ), said side cylinders (110i-110 ₂ ) being positioned:  • on either side of said central tank (106) and connected to said central tank (106),  In / on the lower reservoir (104) and connected to said lower reservoir (104),  Under said upper reservoir (102) and connected to said upper reservoir (102); - a crank-connecting device (142) rigidly connected to at least one, in particular to the two pistons (112i-112 ₂ ), provided to be rotated, alternatively by said pistons (112i-112 ₂ ); characterized in that - each piston (112i-112 ₂ ) is driven in translation in its side cylinder (110i-110 ₂ ) downwards by the working liquid flowing from the upper reservoir (102), and - said piston (112i-112 ₂ ) drives the other piston upwards and the rotation of said connecting rod device (142). 2. System (100; 200; 300; 400) according to the preceding claim, characterized in that: - each piston (112ι-112 ₂ ) is driven in translation in its cylinder downwards, to a predetermined position, so that said piston (112i-112 ₂ ) transfers working liquid (108), previously admitted in said cylinder (110i-110 ₂ ) from the lower reservoir (104), to said central reservoir (106) thereby causing said liquid (108) to be transferred from the central reservoir (106) to the upper reservoir (102), and when said piston (112i-112 ₂ ) reaches said predetermined position, it releases an opening in said lateral cylinder (110i-110 ₂ ) allowing the evacuation of the working liquid (108) discharging into said lateral cylinder (110i-110 ₂₎ to the lower tank (104), thus causing the transfer of the working liquid (108) in said lower tank (104) in the other lateral roller (110i-110 _2). 3. System (100; 200; 300; 400) according to any one of the preceding claims, characterized in that it comprises, for each lateral cylinder (110i-110 ₂ ), a conduit, said upper (114i-114 ₂ ), connecting the upper reservoir (102) to said lateral cylinder (110i-110 ₂ ) and allowing the transfer of the working liquid (108) from the upper reservoir (102) to said cylinder (110i-110 ₂ ). 4. System (100; 200; 300; 400) according to the preceding claim, characterized in that the diameter of at least one upper duct (114i-114 ₂ ) is between 1 cm and 50 cm, in particular equal to 5 cm, and in that the height of at least one upper duct (114i-114 ₂ ) is between 0.5 m and 50 m, in particular equal to 5 m. 5. System (200; 300; 400) according to any one of the preceding claims, characterized in that the crank-connecting device (142) is disposed under the upper reservoir (102). 6. System (100; 200; 300; 400) according to the preceding claim, characterized in that it comprises at least one turbine (126) positioned so as to be driven by the working liquid (108) transferred from the central tank (106) to the upper reservoir (102), in particular said turbine (126) is positioned at the outlet of the central conduit (124). 7. System (100; 200; 300; 400) according to any one of the preceding claims, characterized in that each side cylinder (IIO1-IIO2) comprises a check valve, said lower (II81-II82), arranged on the bottom wall of said side cylinder (IIO1-IIO2) and facing the lower tank (104), and provided to allow the passage of the working liquid (108) from the lower tank (104) to said cylinder (IIO1-IIO2). 8. System (100; 200; 300; 400) according to any one of the preceding claims, characterized in that the upper reservoir (102) comprises two check valves, called upper (II61-II62), each giving on a side cylinder (IIO1-IIO2), and provided to allow the passage of the working liquid (108) from the upper reservoir (102) to said side cylinder (IIO1-IIO2). 9. System (100; 200; 300; 400) according to any one of the preceding claims, characterized in that it comprises, for each lateral cylinder (IIO1-IIO2), a so-called lateral duct (I2O1-I2O2), connecting said cylinder (11OI-IIO2) to the central tank (106) and comprising a so-called lateral check valve (122i-1222) provided to allow the passage of the working liquid (108) from said cylinder (IIO1-IIO2) to the central tank (106). 10. System (200; 300; 400) according to any one of the preceding claims, characterized in that each lateral cylinder (IIO1-IIO2) comprises at least one orifice (2O81-2O82) arranged on one side of said lateral cylinder (IIO1 -IIO2), provided for the admission of air into said cylinder (IIO1-IIO2). 11. System (100; 200; 300; 400) according to any one of the preceding claims, characterized in that it comprises, for each lateral cylinder (IIO1-IIO2), a conduit, said exhaust (1281-1282 ), connecting the opening of said cylinder (IIO1-IIO2) to the lower tank (104) and allowing the transfer of the working liquid (108) from said cylinder (IIO1-IIO2) to the lower tank (104). 12. System (200; 300; 400) according to the preceding claim, characterized in that it comprises at least one duct, said air (204i-204 ₂ ), connecting an upper duct (114i-114 ₂ ) to the duct central (124), adapted to transfer air from the upper conduit (IOO-I IO2) to said central conduit (124). 13. System (100; 200; 300; 400) according to any one of claims 8 or 9, characterized in that each upper duct (114i-114 ₂ ) comprises an inlet opening (206i-206 ₂ ) of air and / or exhaust air. 14. System (300) according to any one of the preceding claims, characterized in that it comprises, for at least one cylinder (I IO1-I IO2), an air reservoir (302i-302 ₂ ), arranged in said cylinder (I 10-I IO2) under the piston (112i-112 ₂ ) of said cylinder (I IOI-I IO2). 15. System (400) according to any one of the preceding claims, characterized in that it comprises a first air compression device (402) comprising: a first cylinder (404i-404 ₂ ) comprising a first piston (406-406 ₂ ) connected to a lower valve (I-81-I I82), a second cylinder (404i-404 ₂ ) comprising a second piston (406-406 ₂ ) connected to the other lower valve (I-I81-I I82), and - an air duct (408) connecting said cylinders (404i-404 ₂ ) to each other and to the central duct (124).