FR3062427A1 - ENERGY PRODUCTION DEVICE INVOLVING ARCHIMEDE PUSH - Google Patents

Abstract

Device (1) for producing mechanical energy from buoyancy, which comprises: - a tank (2) provided with a pair of side walls (3) facing each other; - A drum (7) rotatably mounted relative to the vessel (2) and provided with cells (12) uniformly distributed, and floats (13) housed in the cells (12); a separator (15) mounted in the tank (2), comprising a pair of separating partitions (17) delimiting, respectively with the tank (2), a primary space (21) and an isolated secondary space (22); one of the other in a sealed manner; a predetermined volume (23) of liquid which at least partially fills the primary space (21), the secondary space (22) being filled with air and sealingly isolated from the primary space (21).

Description

Holder (s):

RUIZ DIEZ JOSE ANTONIO.

O Extension request (s):

® Agent (s): LOUIS PETIT.

© ENERGY PRODUCTION DEVICE USING ARCHIMEDIC PUSH.

FR 3 062 427 - A1

@) Device (1) for producing mechanical energy from Archimedes' thrust, which includes:

- a tank (2) provided with a pair of facing walls (3);

- A drum (7) mounted in rotation relative to the tank (2) and provided with cells (12) uniformly distributed, and floats (13) housed in the cells (12);

- a separator (15) mounted in the tank (2), comprising a pair of partition walls (17) delimiting respectively, with the tank (2), a space (21) primary and a space (22) secondary isolated one of the other in a sealed manner;

- A predetermined volume (23) of liquid which at least partially fills the primary space (21), the secondary space (22) being filled with air and sealingly isolated from the primary space (21).

Energy production device involving Archimedes' push

The invention relates to the production of energy, more precisely from the combined effects of Archimedes' push and universal gravitation.

It is known that, in a uniform gravity field, any body of volume V immersed in a fluid (in particular liquid) undergoes a force oriented upwards (that is to say opposite to the general direction of its own weight), called Archimedes' push. The value of Archimedes' thrust, noted P _A , is provided by the following formula:

P _A = —M _f g where:

M _f is the mass of fluid contained in the volume V, g is a gravity field.

We have always sought to take advantage of the flotation of bodies to convert the energy supplied by Archimedes' push into mechanical work.

This conversion is used in particular by wave power plants, for which the applicant has proposed promising solutions, cf. eg. French patent FR2992626 (or its European equivalent EP28671 15), which proposes a power station equipped with floats whose alternative movements of ascent and descent caused by the swell are converted into rotation of a tree.

Unsuccessful research has also been carried out to entrain, thanks to Archimedes' push, a body in a cyclical movement producing mechanical work.

The present invention contributes to this research, by proposing a device for producing mechanical energy from Archimedes' thrust, which comprises:

a tank provided with a pair of substantially parallel side walls;

a drum mounted in rotation relative to the tank about an axis of rotation, this drum being integral with a shaft which extends along the axis of rotation of the drum, which comprises a cylinder provided with cells uniformly distributed at the periphery of the cylinder, and sealed hollow floats each secured to the cylinder and housed in a cell, the cylinder extending between two lateral end faces which each extend opposite a side wall of the tank;

a separator mounted in the tank, which defines a central housing in which the drum extends, this separator comprising a pair of partition walls which each extend on either side of the housing between a lateral face of the cylinder and a side wall of the tank, each partition being provided with an oblique lower section which extends from a bottom of the tank to the vicinity of the axis of the drum, each partition having a lower face turned towards the bottom of the tank and an opposite upper face, the upper face and the lower face respectively delimiting, with the tank, a primary space and a secondary space insulated from each other in a sealed manner;

a predetermined volume of liquid which at least partially fills the primary space, the secondary space being filled with air and sealingly isolated from the primary space.

According to various characteristics, taken alone or in combination: each partition has, in the extension of the lower section, a middle section separated from the tree on the side of the primary space;

the separator comprises a pair of cheeks from which the separators extend, and a cylindrical ferrule which connects the cheeks and with which these delimit the housing for the drum;

an annular gap is formed between the ferrule and the periphery of the drum, and the separator comprises a seal interposed between the ferrule and the periphery of the drum, in the vicinity of the lower section;

seals with a low coefficient of friction are interposed between the cheeks and the lateral faces of the cylinder;

the volume of liquid fills the primary space up to under the floats at their maximum altitude;

the drum has a space between each float and its cell, and spacers are interposed between each float and its cell;

the drum includes a series of drainage holes drilled in the cylinder along its periphery.

Other objects and advantages of the invention will emerge in the light of the description of an embodiment, given below with reference to the appended drawings in which:

FIG.1 is a perspective view, partially broken away, of an energy production device according to the invention;

FIG.2 is a sectional view of the device of FIG.1, along the section plane II-II.

FIG. 1 shows a device 1 for producing mechanical energy from Archimedes' thrust and gravitation.

This device 1 comprises, firstly, a tank 2 provided with a pair of facing side walls 3. In the example illustrated, these side walls 3 are parallel; they are e.g. connected by end walls 4. The tank 2 further comprises a bottom 5 from which the walls 3, 4 extend. According to an embodiment illustrated in the drawings, the tank 2 is parallelepipedal but this example is not limiting. In FIG. 1, the wall 3 located on the side of the observer and the end wall 4 are partially torn off for reasons of clarity. We understand that in practice these walls are full.

Each side wall 3 has an internal face 6 which advantageously has a good coefficient of friction and / or is provided with a coating having a good coefficient of friction.

The device 1 comprises, secondly, a drum 7 rotatably mounted relative to the tank 2 around an axis X of rotation. In the example illustrated, where the side walls 3 of the tank 2 are (at least locally) plane and parallel, the axis X of rotation of the drum 7 extends perpendicular to the side walls 3.

The drum 7 is integral (at least in rotation) with a shaft 8 which extends along the axis X of rotation. The drum 7 comprises a cylinder 9 which can be made of a metallic material (eg steel, an aluminum or copper alloy) or plastic (eg PTFE or polytetrafluoroethylene). Alternatively, the cylinder 9 can be made of any rigid material, and coated with a material with a low coefficient of friction Le (eg a bronze or a PTFE). The cylinder 9 extends between two lateral end faces 10, 11 which each extend opposite a side wall 3 of the tank 2.

The cylinder 9 is provided with cells 12 uniformly distributed around its periphery, and with floats 13. Each float 13 is hollow, sealed, integral with the cylinder 9 and housed in a cell 12 so that a space 14 is formed between them, preferably all around the float

13.

According to an embodiment illustrated in the figures, each cell 12 is cylindrical and extends substantially parallel to the axis X of rotation of the drum 7, while, correspondingly, each float 13 is also cylindrical (of diameter less than alveolus 12). Note that the cylindrical shape is not provided by way of limitation but only for illustration, any other shape may be suitable.

In the example illustrated, the cells 12 and the floats 13 are four in number, but this number cannot be considered to be limiting, any more than their outline when viewed in section. The cylinder 9 could thus be provided with a series of adjacent hollow sectors (each constituting a cell 12) in each of which would be housed a float 13 of corresponding shape.

The device 1 comprises, thirdly, a separator 15 mounted in the tank 2, which defines a central housing 16 in which the drum 7 extends. The separator 15 is preferably in the form of a sheet whose thickness is small with regard to its other dimensions (and in particular the diameter of the central housing 16).

This separator 15 comprises a pair of dividing partitions 17 which each extend on either side of the housing 16 between a lateral face 10 of the cylinder 9 and a lateral wall 3 of the tank 2. The contact between each partition 17 of separation and the corresponding side wall 3 is advantageously sealed. A gasket can, for this purpose, be interposed between them.

Each partition 17 is moreover provided with an oblique lower section 18 which extends from the bottom 5 of the tank 2 to the vicinity of the axis X of rotation of the drum 7, each lower section 18 being offset from the vertical of the axis X of rotation of the drum 7 in such a way that, when a float 13 exceeds this section 18 during the rotation of the drum 7, it is no longer vertical to the axis X of rotation.

Each partition 17 has a lower face 19 facing the bottom 5 of the tank 2, and an opposite upper face 20. When the tank 2 opens out on the side opposite the bottom 5, the upper face 20 faces the opening of the tank 2.

The upper face 20 and the lower face 19 respectively delimit, each with the tank 2, a primary space 21 (to the left of the partition 17 in FIG. 2) and a secondary space 22 (to the right of the partition 17 in FIG. .2) isolated from each other in a leaktight manner both at the bottom 5 and on the side walls 3.

The device 1 comprises, fourthly, a predetermined volume 23 of liquid (for example water or oil) which at least partially fills the primary space 21 (in the example illustrated, the volume 23 of liquid fills the primary space 21 as far as the floats 13 at their maximum altitude, but this example is not limiting), while the secondary space 22 is filled with air and insulated in a sealed manner from the primary space 21.

The lower section 18 of each partition 17 forms, with the vertical, an angle A which is advantageously between 15 ° and 45 °, and for example. about 35 °.

As illustrated in the drawings, each partition 17 has, in the extension of the lower section 18, a middle section 24 spaced from the shaft 8 on the side of the primary space 21 and which forms a baffle around it.

Furthermore, the separator 15 advantageously comprises a pair of cheeks 25 from which the partitions 17 extend, and a cylindrical ferrule 26 which connects the cheeks 25 and with which these delimit the housing 16 for the drum 7.

According to a preferred embodiment illustrated in the figures, and more particularly visible in FIG. 2, an annular interstice 27 is formed between the ferrule 26 and the periphery of the drum 7. In operation, this annular interstice 27 is filled with air . However, in the vicinity of the lower section 18, the separator 15 comprises a seal 28, interposed between the ferrule 26 and the periphery of the drum 7. This seal 28 has the function of limiting the infiltration of liquid between the space 21 primary and gap 27.

This seal 28 is advantageously made from a material with a low coefficient of friction (eg PTFE) or from any material coated with such a material with a low coefficient of friction.

Furthermore, seals (preferably also made of a material with a low coefficient of friction or in any material coated with such a material with a low coefficient of friction) are preferably interposed between the cheeks 25 and the faces 10 side of the cylinder 9, so as to complete the liquid tightness between the primary space 21 and the gap 27.

In practice, it is preferable that the contact is intimate (although slippery) between the side faces 10 of the cylinder 9 and the cheeks 25, so as to minimize infiltration.

According to a preferred embodiment illustrated in FIG.2, the drum 7 comprises, for each float 13, spacers 29 interposed between the latter and its cell 12, so as to stiffen the drum 7 and in particular the mounting of the float 13 with respect to cylinder 9.

These spacers 29 can be attachments or be formed in a single piece with the cylinder 9.

According to a preferred embodiment illustrated in FIG. 2, the drum 7 comprises, for each cell 12, a plurality of spacers 29 uniformly distributed around the periphery of the float 13, to maintain a uniform space between it and the alveolus 12, immobilize the float 13 relative to the cylinder 9 and avoid its deterioration.

The drum 7 may further include a series of drainage holes 30 drilled in the cylinder 9 along its periphery. If the cylinder 9 is hollow, the holes 30 will be lined to avoid the accumulation of liquid in the cylinder 9.

According to an embodiment illustrated in FIG.1, the device 1 comprises a current generator 31 coupled to the shaft 8 by means of a transmission by gear, belt, chain, or equivalent. In the example illustrated, the transmission is done by means of a belt 32 which circulates on a wheel 33 (or a pulley) integral in rotation with the shaft 8, and on a pinion 34 integral with a shaft 35 of generator input 31.

The current generated is transported out of the generator 31 by means of electric cables 36, which can be connected directly to the network (in particular local or metropolitan), or to one or more storage battery (ies).

The device 1 operates in the following manner.

The number of floats 13 and their distribution are such that a float 13 is always in the primary space 21, embedded in the volume 23 of liquid. The buoyancy which is exerted on the float 13 due to the liquid which surrounds it (in the space 14 between the float 13 and the cell 12) drives it upwards and consequently induces a driving torque. on the drum 7, which is thus driven in rotation about its axis X. The shaft 8, integral with the drum 7, is itself driven in rotation and, coupled to the generator 31, allows the production of electricity.

When the float 13 exceeds the water line of the liquid, the rotation of the drum 7 has already placed another float 31 in the primary space 21. No sooner has the float 13 entered the primary space 21 than the space 14 which surrounds it is filled with liquid. Since the lower section 18 of the separator 15 is offset from the vertical of the axis X of rotation of the drum 7, the float 13 is subjected to a force generating a driving torque on the drum 7.

In theory, there is therefore nothing to prevent the rotation of the drum 7 thus continuing (in the direction indicated in FIG. 2 by the arrow). Any liquid infiltration from the primary space 21 to the secondary space 22 can be drained by means of the orifices 30, which drain the liquid and drain when they exceed the flotation surface.

Claims (8)

1. Device (1) for producing mechanical energy from Archimedes' thrust and gravitation, which comprises: a tank (2) provided with a pair of facing side walls (3); a drum (7) mounted in rotation relative to the tank (2) about an axis (X) of rotation, this drum (7) being integral with a shaft (8) which extends along the axis ( X) for rotation of the drum (7), which comprises a cylinder (9) provided with cells (12) uniformly distributed around the periphery of the cylinder (9), and sealed hollow floats (13) each secured to the cylinder (9) and housed in a cell (12), the cylinder (9) extending between two lateral end faces (10) which each extend opposite a side wall (3) of the tank (2); a separator (15) mounted in the tank (2), which defines a central housing (16) in which the drum (7) extends, this separator (15) comprising a pair of partition walls (17) which s' each extend on either side of the housing (16) between a side face (10) of the cylinder (9) and a side wall (3) of the tank (2), each partition (17) being provided with a section (18) lower oblique which extends from a bottom (5) of the tank (2) to the vicinity of the axis (X) of the drum (7), each partition (17) having a face (19) lower facing towards the bottom (5) of the tank (2) and an opposite upper face (20), the upper face (20) and the lower face (19) respectively delimiting, with the tank (2), a space (21 ) primary and a secondary space (22) insulated from each other in a sealed manner; a predetermined volume (23) of liquid which at least partially fills the primary space (21), the secondary space (22) being filled with air and sealingly isolated from the primary space (21). 2. Device (1) according to claim 1, characterized in that each partition (17) has, in the extension of the lower section (18), a middle section (24) spaced from the shaft (8) on the side of the primary space (21). 3. Device (1) according to claim 1 or claim 2, characterized in that the separator (15) comprises a pair of cheeks (25) from which extend the separators (15), and a ferrule (1) cylindrical which connects the cheeks (25) and with which these delimit the housing (16) for the drum (7). 4. Device (1) according to claim 3, characterized in that an annular gap (27) is formed between the ferrule (26) and the periphery of the drum (7), and in that the separator (15) comprises a seal (28) interposed between the ferrule (26) and the periphery of the drum (7), in the vicinity of the lower section (18). 5. Device (1) according to claim 3 or claim 4, characterized in that it comprises seals with a low coefficient of friction interposed between the cheeks (25) and the sides (10) of the cylinder (9) ). 6. Device (1) according to one of the preceding claims, characterized in that the volume (23) of liquid fills the space (21) primary as far as the floats (13) at their maximum altitude. 7. Device (1) according to one of the preceding claims, characterized in that the drum (7) has a space (14) between each float (13) and its cell (12), and in that it comprises spacers interposed between each float (13) and its socket (12). 8. Device (1) according to one of the preceding claims, characterized in that the drum (7) comprises a series of drainage holes (30) drilled in the cylinder (9) along its periphery. 1/2