BE1029029B1 - CONVERSION SYSTEM OF ARCHIMEDES THRUST INTO HYDROELECTRIC ENERGY - Google Patents

Abstract

The present invention relates to a hydroelectric power generation system comprising: - a body of water resting on a bottom and whose level varies with time between a minimum level and a maximum level; - a float (1); - an anchor (2) secured to said bottom; - an energy conversion unit (8) comprising a winder/unwinder (9), a multiplier (10) and an electricity generator (11), said winder/unwinder (9) being able to actuate said power generator electricity (11) via said multiplier (10); - at least one cable (6) connecting on the one hand the float (1) at a first end and on the other hand the winder/unwinder (9) at a second end, via a plurality of return pulleys (13) , of which at least one is anchored to the bottom of the water; characterized in that the system also comprises a tackle (3), said tackle (3) comprising at least two blocks, a lower block (4) fixed and hooked to the bottom of the water via the anchor (2) and a block upper part (5) movable and connected to a lower part of the float (1), and characterized in that, in use, with the variation of the water level, the float (1) moves vertically under the effect of the thrust Archimedes and, via the hoist (3), drives the cable (6) in traction, said cable (6) unwinding from the winder/unwinder (9), the rotation of said winder/unwinder (9) causing the actuating said generator (11) via the multiplier (10) to generate electricity.

Description

CONVERSION SYSTEM FROM ARCHIMEDES THRUST TO

HYDROELECTRIC ENERGY Subject of the invention

The present invention relates to the field of hydroelectricity and the use of movements of water masses, such as tides, to create electricity. In particular, the present invention relates to the conversion of Archimedes thrust into electrical energy. State of the art

[0002] At the present time, energy requirements, and in particular electricity requirements, are constantly increasing. In addition, environmental protection and the fight to slow down global warming advocate energy production techniques that emit neither radioactive waste nor greenhouse gases. Out of more than twenty renewable energy sources listed (http://energiein.e-monsite.com/pages/60-la-poussee-d-archimede.html), eight use energy from the sea or, more generally , water and only one refers to the use of Archimedean thrust.

[0003] Archimedes' thrust is the force experienced by a body immersed in a fluid and subjected to a field of gravity. This force, exerted opposite to the gravity which gives it birth, is directed vertically, from bottom to top, with an intensity equal to the weight of the volume of fluid displaced. It is expressed in newtons (N) and is a function of the density of the fluid, the displaced volume and the acceleration due to gravity. In water with a mass — density of 1,000, an immersed volume of 1m3 develops a force of 9,807 N.

[0004] The energy of the sea can come from the swell of the waves, from the backwash along the coasts, from the sea currents, from the tidal currents (tidal energy), from the differences in temperature or from the osmotic overpressure of the water salty. On land, water can also generate energy if it is held in a dam or reservoir, or if it is subject to movement or a current.

[0005] There is a real interest in transforming this energy linked to the movement of water masses into electricity. In most systems, water drives a turbine or pump that feeds a reservoir.

[0006] The systems intended for use at sea are generally actuated by the movement of the waves. These systems include floats, pistons, pumps, etc. Some documents disclose the use of Archimedes' principle to recover the energy caused by the movement of water.

[0007] The document US 2007/018458 A1 describes a system making it possible to extract the energy from the movement of waves and tides thanks to traction exerted by a float on a cable. Specifically, the system includes two weights located in the sea, connected by a cable. This cable passes through a pulley attached to a float, the pulley therefore being on the surface of the water. The weights are sized so that one is heavier than the other, so they rest on the seabed floor. When the surface of the water rises, due to the action of the tide, the float rises, which also raises the lighter weight (i.e. the counterweight). The heaviest weight is sized to stay fixed on the bottom of the water, while the counterweight moves up and down as the float moves with the tide. These movements of the counterweight allow the pulley to rotate. This rotation is then transformed into usable energy thanks to a conversion system.

[0008] GB 2 479 348 A discloses a wave energy converter using the relative motion between a floating part and a static part to rotate a coil of an electromechanical device on which a rope is wound, the coil being connected to an electric motor/generator via a ratchet mechanism and a gearbox. The coil is also connected to a return spring via a second gearbox. The electromechanical device can be located in a floating float (Fig. 1) which can be a boat (Fig. 5) or at the static end of the rope, such as on the seabed or the shore (Fig. 4). The motor/generator can be used to drive the spool to adjust the length of the rope to the conditions of the deployment environment. In another embodiment, more than one floating part is connected to a single electromechanical device (Fig. 3). Aims of the invention

The present invention aims to provide a new system for converting into electricity, thanks to Archimedes' thrust, the energy linked to the variation in the level of liquid.

The invention aims in particular to use the energy resulting from the traction on a cable exerted by a float moving with the variation of the water level.

The present invention also aims to provide a solution for improving the performance of systems using the movement of water masses to generate energy, in particular electricity.

Another object pursued by the invention is to provide a simple system, the implementation of which does not necessarily have to be carried out by skilled labor specifically in underwater construction, and with repair costs and affordable maintenance.

[0013] Yet another object is to propose an energy supply system having a low impact on the environment. Main characteristic elements of the invention

The present invention relates to a hydroelectric power generation system comprising: - a body of water resting on a bottom and whose level varies with time between a minimum level and a maximum level; - a float; - an anchor fixed to the bottom;

- An energy conversion unit comprising a winder/unwinder, a multiplier and an electricity generator, the winder/unwinder being able to actuate the electricity generator via the multiplier; - at least one cable connecting on the one hand the float at a first end and on the other hand the winder/unwinder at a second end, via a plurality of return pulleys, at least one of which is anchored to the bottom some water ; the system also comprising a hoist, said hoist comprising at least two blocks, a fixed lower block attached to the bottom of the water via the anchor and a movable upper block connected to a lower part of the float, and in use, with the variation in the water level, the float moving vertically under the effect of Archimedes' thrust and, via the hoist, driving the cable in traction, the cable unwinding from the winder/unwinder, the rotation of the winder/unwinder causing actuation of the generator via the multiplier to generate electricity; characterized in that the system comprises a brake located on the cable or on the energy conversion unit intended to slow down/block the drive movement thereof, the brake being controlled by water level detectors, in order to release the float only when the water level has reached its maximum level.

[0015] According to preferred embodiments of the invention, the hydroelectric power generation system further comprises one of the following characteristics, or an appropriate combination thereof: - each muffle comprises at least two sheaves, the muffles being connected by a rope running around the sheaves; - the energy conversion unit is on land or on a ship or barge; - the energy conversion unit is located on the emergent surface of the float and the cable rises vertically in a tube placed between the lower and upper surfaces of the float and passing through the center of gravity of said float;

- the cable entry into the tube is protected by a winch cable guide with four pivoting rollers which hold the cable in a central position and limit parasitic friction; - the electricity generator is a dynamo or an alternator; 5 - the system includes a holding buoy connected to the float and moored to the bottom of the water, which substantially prevents the float from rotating on itself; - the winder/unwinder comprises a reel, the axis of which is, at one of its ends, in connection with the multiplier to which it transmits its rotary movement and at the other of its ends, in connection with a suitable device to ensure the rewinding of the cable; - part of the cable and the hoist remain permanently submerged; - the system includes an electric assistance to wrap the cable around the reel/reel, once the float goes down with the downward movement of water.

The invention also relates to the use of the above system in the sea, in a lock, an airlock or a well, or in any other place in which a body of water can be the seat of an increase and a decrease in level.

Brief description of figures

[0017] Figure 1 shows a sectional view of an embodiment of a system according to the present invention, the system being located at sea.

[0018] Figure 2 shows a plan view of the system of Figure 1.

Figure 3 shows a detail view of the system of Figure 1 which schematically shows an example of block hoist used. Description of a preferred embodiment of the invention

The present invention relates to a system for converting the energy associated with the movement of a body of water into electrical energy. As illustrated in Figure 1, the system comprises a float 1 connected to the bottom of the water by a cable 6. The cable 6 is fixed at one of its ends to the bottom of the water by an anchor 2. The other end of the cable 6 is wound around a winder/unwinder 9 belonging to a conversion group 8. The winder/unwinder 9 and the conversion group 8, as explained in more detail below, can be on dry land or on the aforementioned float. With the variation of the water level, and in particular according to the present invention, with the rise of the water level with the rising tide for example, the float 1 moves vertically, driving the cable 6 which unwinds from the reel / unwinder 9.

The system of the present invention therefore uses Archimedes' principle which is exerted linearly from the center of the Earth. Float 1 rises vertically with the water level, and develops a pulling force proportional to the volume of liquid it displaces and the density of the liquid. This tensile force is transformed thanks to the cable 6, into a rotational force which is applied to the winder/unwinder 9 around which the cable 6 is wound. The winder/unwinder 9 is thus driven by a rotary movement resulting from the necessarily linear movement resulting from Archimedes' thrust. This rotary motion is used to produce hydroelectricity from a new origin by means of a generator 11, for example a dynamo or an alternator.

The system of the present invention can be applied wherever a body of water is the seat of a level rise. At sea, it is the movement of the tide. On land, this may be the case whenever a volume of water is trapped in a well-shaped reservoir, for example if it is adjacent to a lock or fed by a waterfall.

In order to optimize the aforementioned energy transformation, the system according to the present invention advantageously makes use of a block hoist 3. The block is made up of an assembly of several sheaves (or pulleys) on the same yoke (the same axis). The number of sheaves is preferably the same on both blocks. A line passes successively from a sheave of the first block to a sheave of the second block and vice versa, to form a number of strands which is equal to the number of sheaves.

In the present case, as shown schematically in Figure 3, the hoist 3 is thus composed of two groups of sheaves 7 divided into two blocks. The first block, the lower block 4, is fixed and attached to the bottom of the water via the anchor 2. The second block, the upper block 5, is mobile and connected to the lower part of the float 1. Between the lower part of the float 1 and the anchor 2 located at the bottom of the water, the cable 6 therefore consists of a rope which passes successively from one block to the other of this hoist 3. At the end of the hoist, the cable joins the winder/unwinder 9 which actuates the generator 11, either directly from the upper block, or from the lower block by turning around the return pulley(s) 13. The hoist 3 makes it possible to increase the speed of movement of the cable 6 and consequently the speed of rotation of the winder/unwinder 9. The starting point of the rope is fixed indiscriminately on one or the other block but the last sheave 7 which must send the cable towards the generator group 11 is preferably located on the muffle - lower fixed 4. Whatever the arrangement n adopted, the gearing power of the hoist 3 is proportional to the number of strands, i.e. to the number of passages made by the rope between the two assemblies of sheaves 7 which each constitute blocks 4, 5.

The upward vertical movement of the float 1 is transformed into traction transmitted to the generator 11 by the assembly consisting of the sheaves 7 and the cable 6. At the start of each rising tide cycle, the cable 6 is wound to the maximum around the winder/unwinder 9 whose rotation will be induced by the unwinding of the cable 6. This rotation is transmitted to the electric generator 11 through a multiplier 10 which adapts the speeds to values essential for the proper functioning of the various elements. As the water begins to rise, float 1 held by hoist 3 gradually sinks into the water and begins to exert its pulling power. To best benefit from its upward power, the resistance exerted by group 8 must be adapted to keep float 1 submerged as much as possible. At the beginning of the descent of the water, the float 1 gradually comes out of the water before losing all traction power. During its descent, it is driven downwards not only by gravity because of its mass but also, advantageously according to the invention, by a reduced power electric assistance generated by the group 8 which ensures the correct movement of the hoist and the winding of the cable 6 around the winder/unwinder 9.

In an improved version of the invention, in order to increase the power of the installation, the system may include a brake or any blocking mechanism (not shown) acting on the movement of the electricity generator 11. This brake is controlled by water level detectors, so as to release the float 1 from its lower position only when the water level has reached its maximum level. Indeed, it is interesting to maintain the float 1 as the water level rises so that it remains completely submerged, and only to release the brake of the generator 11 once the water is at its level. maximum. The brake can act either on the cable 6, or on the winder/unwinder 9, or at the level of the multiplier mechanism 10 of the speed of rotation of the generator 11. By maintaining the float completely submerged, one benefits from all of its force. upward. By releasing it when its course is longest, its speed is increased and the duration of its course is all the more reduced to benefit from all its power.

The group 8 consisting of the winder / unwinder 9, the multiplier 10 and the generator 11 can be on dry land. In this arrangement, the visible portion of cable 6 more easily prevents the pivoting of the float 1 and the twisting of the ropes of the hoist 3.

The conversion group 8 can also be on the surface of the water, on a boat or a barge. In the latter cases, since the level rise is strictly equal for all, several devices can combine their strength if their respective cables 6 act in the same way on the axis of a single winder/unwinder 9. On a boat or a barge, devices can be arranged to port (left) and starboard (right) and act on a single axis of the generator 11 provided that the reels 9 on either side are inversely wound.

[0029] The conversion group 8 can also be located on the emerged surface of the float 1. In the latter case, the cable 6 rises vertically in a tube placed between the lower and upper surfaces of the float 1 and positioned to correspond to its center of gravity. The entry of the cable 6 into the tube is protected, for example, by a cable guide for a winch with four pivoting rollers which hold the cable 6 in the central position and limit parasitic friction.

[0030] In all cases, in order to prevent abnormal twisting of the ropes of the hoist 3, the rotation of the float 1 on itself (pivoting) must be prevented, either directly or by means of a buoy. holding, by a secondary anchoring device fixed at a distance to the bottom. Also for this purpose, the lower block can be attached to the anchorage by a swivel pin equipped, or not, with a bearing. This desirable horizontal stability is also improved if the lower block of the hoist is fitted with a four-roller cable guide which keeps it in the direction of the first return pulley 13.

The float 1 in its entirety having a volume and a weight, the thrust of Archimedes, that is to say the available force, will be the resultant of the useful volume of the whole. The useful volume is the total volume of float 1 minus the volume necessary to ensure buoyancy on the surface of the water. The calculation of this useful volume must also take into account the mass of all of the submerged wiring 6 which will increase as the float 1 rises. The shape of the float 1, which is either in one piece or made up of two or more parts, is relatively unimportant. It can be relatively arbitrary but must be adapted to its environment, in particular at sea. The ratio between the active volume of the float 1 and its surface must be taken into account since a flat shape induces a more abrupt start and end of movement. than a vertically elongated form would produce.

[0032] Whatever the depth of the water below the float 1, the fixing of the assembly must be sufficient to withstand the force of attraction exerted by the float 1. The lower block assembly 4 of the hoist 3 is maintained at the bottom of the water, either by a solidly attached construction, or by an anchoring system 2 which rests on the bottom. In the latter case, in order to sufficiently weigh down the anchor, the lower block 4 is advantageously attached to a solid and heavy structure. It can for example be built in a star with each of the vertices of the star fitted with a guide cable held vertically by a small float (not shown). In a particular embodiment, additional weights can be lowered along the guides to increase the stability of the assembly.

[0033] For proper operation of the system, the height of water under the lower part of the float 1 must be sufficient to ensure that the entire cabled device, namely the cable 6 and the hoist 3, always remains submerged, in particular in sea during the lowest tides. If the float 1 still retains an emerged part, in the form of topsides (emerged part of the hull of a ship above the waterline) in the event that a boat or a barge would serve as a float attached by its hull, it can support the whole current-generating device. Indeed, instead of the latter being on dry land, it can advantageously be on the float 1, as explained previously.

[0034] With regard to the winder/unwinder 9, at the start of the ascent period of the float 1, a length of cable at least equivalent to that which will be submerged at the end of the ascent must be wound on this one. To obtain a higher speed of rotation, the diameter of the winder/unwinder 9 must be as small as possible. The winder/unwinder 9 is made up of a reel, the axis of which is, at one of its ends, in connection with the multiplier 10 to which it transmits its rotary movement and at the other of its ends, in contact with a device which will ensure the rewinding of the cable 6. Furthermore, an electric winch can act as a winder. If the power of its motor and its electrical supply are suitably adapted, it will be able to ensure the rewinding of the cable 6 during the descent of the float 1.

In the transformation unit 8, the multiplier 10 ensures compatibility between the rotational speed of the winder/unwinder 9 and the requirements of the electricity generator 11. For example, at sea, in Nieuwpoort (Belgium), the tidal range , which is the difference in level between high tide and low tide, evolved between 3.0 and 4.8 meters in July 2020. It is therefore reasonable to consider that on our coast the sea level varies, on average , 4 meters for the duration of each tide. During a rising tide (6 hours), the sea therefore rises by 1 meter in 90 minutes. The float of the present invention thus rises at a speed of 1.11 cm/min. If the submerged hoist 3 accelerates the unwinding of the cable 6 20 times (22.22 cm/minute) and if the unwinder has a diameter of 3.50 cm (and, therefore, a circumference of 10.99 cm), this unwinder will be animated by an angular speed of 2.02 rpm. In this case, if the generator requires to turn at 1,200 rpm, the multiplier will have to accelerate approximately 600 times (exactly 594 times) the rotation coming from the winder. Such multipliers are used for example in wind turbines whose blades rotate at 15 rpm and whose alternator requires to rotate at 1,500 rpm. On land, in a lock, since the change in water level typically raises the float by 1 m or 100 cm per minute (instead of 1.11 cm/min at sea as indicated above) the multiplication requirements are 90 times smaller (exactly 90.09 times). If we have in this case, as proposed at sea, a submerged tackle which accelerates the unwinding of the cable 20 times (i.e. 2,000 cm/min), with the same reel 3.5 cm in diameter and 10.99 cm in circumference , the rotary movement will be 181.98 rpm and the need for multiplication will be reduced to 6.59 times to rotate the same alternator at 1,200 rpm. Use

As explained above, the system of the present invention can be applied wherever a body of water is the site of an increase in level. It can therefore be used at sea, thanks to the movements of the tides, but also on land, by creating variations in water volumes (reservoirs, wells, locks, etc.).

[0037] At sea, the system can be associated with or operate in conjunction with any wave energy capture process. Electricity is thus produced from the upward movement of a float for the duration of each rising tide, i.e. for twice six hours a day.

[0038] On land, electricity is produced in a similar way from the upward movements of a vertically moving float at each filling phase of a cistern in the form of a chimney or a well. This well can be adjacent to a lock or be connected to a waterfall or waterfall. In the case of a lock, in order to preserve the entire surface of the airlock which accommodates the boats, the device can preferably be located in an annex well supplied, for example, at its lower level and undergoing the same variations in the water level. of the lock.

[0039] In the case of a waterfall, since there is a significant drop, the upward movement of the float can take place in an adjacent column which fills, for example, at its upper level by a diversion of the water current. . In this case, emptying is permitted by the opening of a lower device triggered by the arrival of the float at its highest point.

[0040] In the case of a well, the pivoting of the float can be advantageously prevented by means of a tether which slides up and down in a tube or a groove integral with the wall.

[0041] Even if the energy potential of the tides is immeasurably higher, the terrestrial devices have the triple advantage of experiencing much faster filling speeds than those produced by the rise in water level due to the tides, of being able to be operated 24 hours a day and to be located anywhere on the continents, regardless of the coastline. In addition, the efficiency of the land system increases if the energy contained in the drain water of a well is recovered by a turbine placed downstream and/or if the filling water already drives a turbine placed upstream of the well. all. Advantages

[0042] The innovation of the concept lies in the fact that it aims to take advantage of Archimedes' principle, but using traction on a cable by a float rising with the water level, contrary to the documents of the state of the art which use weights sinking in the water, and therefore having to be guided during their descent. In addition, thanks to the use of a hoist, the power developed by the float is multiplied and a better yield is thus obtained. List of reference symbols 1 Float

2 Anchor 3 Hoist 4 Fixed lower block Mobile upper block 6 Cable 7 Hoist sheaves 8 Conversion unit 9 Winder/unwinder Gearbox 11 Generator 12 Buoy 13 Return pulley

Claims (11)

1. Hydroelectric power generation system comprising: - a body of water resting on a bottom and whose level varies with time between a minimum level and a maximum level; - a float (1); - an anchor (2) secured to said bottom; - An energy conversion unit (8) comprising a winder/unwinder (9), a multiplier (10) and an electricity generator (11), said winder/unwinder (9) being able to actuate said generator electricity (11) via said multiplier (10); - at least one cable (6) connecting on the one hand the float (1) at a first end and on the other hand the winder/unwinder (9) at a second end, via a plurality of return pulleys (13) , at least one of which is anchored to the bottom of the water; the system also comprising a hoist (3), said hoist (3) comprising at least two blocks, a lower block (4) fixed and attached to the bottom of the water via the anchor (2) and an upper block (5) movable and connected to a lower part of the float (1), and in use, with the variation of the water level, the float (1) moving vertically under the effect of Archimedes' thrust and, via the hoist (3) , driving the cable (6) in tension, said cable (6) unwinding from the winder/unwinder (9), the rotation of said winder/unwinder (9) causing the actuation of said generator (11) via the multiplier (10 ) to generate electricity; characterized in that the system further comprises a brake, located on the cable (6) or on the energy conversion unit (8), intended to slow down/block the drive movement thereof, the brake being controlled by water level detectors, in order to release the float (1) only when the water level has reached its maximum level. 2. System according to claim 1, characterized in that each block (4, 5) comprises at least two sheaves (7), said blocks (4, 5) being connected by a rope rotating around the sheaves (7). 3. System according to claim 1, characterized in that the energy conversion unit (8) is located on land or on a boat or a barge. 4. System according to claim 3, characterized in that the energy conversion unit (8) is located on the emergent surface of the float (1) and in that the cable (6) rises vertically in a tube placed between the lower and upper surfaces of the float (1) and passing through the center of gravity of said float (1). 5. System according to claim 4, characterized in that the entry of the cable (6) into the tube is protected by a cable guide for a winch with four pivoting rollers which hold said cable (6) in the central position and limit parasitic friction . 6. System according to any one of the preceding claims, characterized in that the electricity generator (11) is a dynamo or an alternator. 7. System according to any one of the preceding claims, characterized in that it further comprises a holding buoy (12) connected to the float (1) and moored to the bottom of the water, which substantially prevents the rotation of the float (1) on itself. 8. System according to any one of the preceding claims, characterized in that the winder/unwinder (9) comprises a reel, the axis of which is, at one of its ends, in connection with the multiplier (10) to which it transmits its rotary motion and at the other of its ends, in connection with a device capable of ensuring the rewinding of the cable (6). 9. System according to any one of the preceding claims, characterized in that part of the cable (6) and the hoist (3) remain permanently submerged. 10. System according to any one of the preceding claims, characterized in that it comprises electrical assistance for winding the cable (6) around the winder/unwinder (9), once the float (1) descends with the downward movement of water. 11. Use of the system according to any one of claims 1 to 10 in the sea, in a lock, an airlock or a well, or in any other place in which a body of water can be the seat of an increase and of a decrease in level.