FR2550827A1 - Method and apparatus for producing tidal electric power using the buoyancy energy of the tide - Google Patents

Abstract

The invention relates to a tidal electric power generator comprising a buoyancy tank 2 provided with a buoyancy chamber 3 and a diving discharge valve and giving rise to a buoyancy force and to kinetic energy. The weight of the buoyancy tank 2 is controlled by regulating the level of water in the latter, and instantaneous force being produced by unlocking a brake during ebb and flow of the tide whereas the force, produced by the buoyancy force and/or by the kinetic energy, is constantly transmitted to a pump 11 by a spiral shell-shaped gear. The invention applies to electricity production which can be obtained in great quantities with little loss of energy.

Description

 The present invention generally relates and essentially relates to a method of producing tidal electrical power using the buoyancy energy of the tide and an apparatus or device generating tidal electrical power intended for the execution of said process, as well as the various applications and uses resulting from their implementation and the systems, assemblies, equipment and installations provided with them.

 The invention relates particularly to the transmission of power by the production of energy by means of the repeated upward and downward movement of a buoyancy tank or container as a function of the ebb and flow of the tide.

In the known state of the prior art, the tidal electrical power was generated by the use of a dam or a retaining dam below which a propeller was installed. The propeller was driven in rotation by the ebb and flow of the tide and, thanks to the energy produced by the rotation of said propeller, an electric power production was accomplished. However, the actual execution or implementation of the above process was too difficult and costly. There was also a drawback, namely the enormous loss of energy during the process of transforming tidal energy into electrical power. In summary, the aim of the present invention is to eliminate the above-mentioned drawbacks and to create a process and an apparatus for producing electrical power
tidal wave using the buoyancy energy of the tide from which greater energy can be obtained by controlling the weight of the buoyancy tank or container.

 A second object of the invention is to create a method and an apparatus for the production of tidal electrical power instantaneously using the buoyancy energy of the tide and the kinetic energy produced by regulating or adjusting the weight of the buoyancy tank. .

 A third object of this invention is to use a gear in the form of a torso shell to uniformly maintain the driving or driving driving force of a pump. The aforementioned and other objectives are achieved by using the gear in the form of a torso shell and a brake and by controlling the water level in the buoyancy tank. The gear in the form of the aforementioned torso shell will control or adjust the driving or driving driving force of the pump, so that the driving or driving driving force of said pump remains constant despite the constant vertical movement of the buoyancy tank.

The invention will be better understood and other objects, characteristics, details and advantages thereof will appear more clearly on reading the explanatory description which will follow, referring to the appended schematic drawings given solely by way of nonlimiting example illustrating a currently preferred specific embodiment of the invention and in which
- Figure 1 is a schematic view of an installation generating electrical power driving tide comprising the buoyancy device and the power transmission device;
- Figure 2 is a schematic side view of the buoyancy device and the power transmission device showing the effect of high tide on the buoyancy device;
- Figure 3 is a view similar to Figure 2 and shows the effect of low tide on the buoyancy device;
- Figure 4 shows a partial view of the power transmission equipment;
- Figure 5 is an enlarged schematic view of the gear in the form of a torso shell;
- Figures 6A and 63 show schematic sectional views of the power transmission equipment illustrated in Figure 4 and show the operation of eelui thereof;
- Figure 7 is a schematic view of 1'équipementpcur-Ra energy transmission to water;
- Figures 8A to 8E are schematic views of the valve or valve of the water pump and show the effect of a change of state on the valve or valve; and
- Figure 9 is a schematic view of the blocking or locking device illustrating the operation thereof and its control or command for adjusting the internal water level of the buoyancy tank.

 According to Figure 1, the installation generating electrical power is mounted above piles or pilots I which are established on the seabed. A buoyancy tank 2 slides vertically between the piles or pilots. A balancing buoyancy chamber or enclosure 3 is located below the buoyancy tank 2 and this chamber or enclosure is filled with air in order to maintain a constant buoyancy force of the buoyancy tank 2. A rack 4 and a immersion or discharge valve 19- are mounted on the side wall of the buoyancy tank 2. An air passage orifice 9 is placed on the top of the buoyancy tank 2. A pinion 5 of a power transmission device 22 is fixed in position. The pinion (5) and, thus, the power transmission device will be driven by the rack 4. The power transmission device 22 is located above the buoyancy tank 2. A pump Il and a four-way valve 12 are placed above the transmission apparatus 22.

The pump It is driven by the transmission device 22 for the purpose of pumping seawater or water from the buoyancy tank 2 into a so-called lower tank 17 located above
The four-way valve 12 is controlled or actuated by an appropriate electrical control means, so that the water passageways can be controlled (see FIG. 8A to FIG. 8E). The four lines 13, 14, 15, 16 are respectively connected to the four-way valve 12. The line 13 is connected to the buoyancy tank 2 and the line 16 is connected to the sea.

Line 14 is connected to the lower tank 17. Line 15 is connected through the pump II to an upper tank 18. The upper tank 18 is mounted above the lower tank 17. The water, pumped into the upper tank 18 , is released so as to flow down through the conduit 20 into the generator E which, in turn, produces electrical power. The water passing through the generator is collected or collected in the lower tank 17.

 Figures 2 to 5 illustrate the operation and structure of the buoyancy device, the power transmission device and the gear in the form of a torso shell.

As the buoyancy tank 2 rises or moves up, it increases the value of the pre-existing buoyancy force by reducing the water level inside the buoyancy tank and thereby reducing the weight of said tank. As the buoyancy tank lowers, descends or moves down, it increases the electrical energy by increasing the water level inside the buoyancy tank, thereby increasing the weight of the tank. . The rack4 drives the pinion 5 producing the following chain reaction
a) the rotation of the pinion 5,
b) rotation of the gear wheels
helical or conical 29A, 29B,
c) the rotation of a driven or driven shaft 6,
d) rotation of gear cogwheels
helical or conical,
e) The rotation of the toothed wheel is based on
torso shell 8A, 8B of the
power transmission 22.

 The operation and control of the above device will be described further by the detailed explanation of Figures 8A and 8E.

 Each gear cogwheel in the shape of a torso shell 8A, 8B is of somewhat conical shape. The pitch angle (or helix turn or screw thread angle with respect to the axis 8C in FIG. 5 or angle whose trigonometric tangent is equal to the ratio of the pitch of the teeth to the perimeter of the pitch circle) the gearwheel gear in the form of a crott torso shell with movement from the smallest portion (i.e. small diameter) to the largest portion (clest large diameter) said gear wheel while the pitch remains the same as indicated in FIG. 5. In addition, the toothing of the gear wheel in the shape of a torso shell is formed helically on the surface of this gear wheel in torso shell shape. Therefore, when the gearwheel 7 is rotated, the torso shell gear 81k or 83 is driven and moves along the axis. as a result, the power converter apparatus 23 moves alternately along the shaft 28. The shaft 8C of the gear shell-shaped gearbox 8A or 8B is designed to mesh with the teeth of a pinion. The teeth of the shaft 8C mesh with a pinion 10 of a lever 25 which is urged upwards by a counterweight 26 as indicated in FIG. 7.

The shaft of the pinion 10 is connected to the shaft of the pump 11 by suitable means.

 FIGS. 6A and 6B represent the power transformer apparatus 23. FIG. 6A illustrates the case in which the gear cogwheel in the shape of a torso shell 8A meshes with the gear cogwheel 7 when the buoyancy tank 2 is raised or moved up by buoyancy force. Furthermore, FIG. 6B illustrates the case in which the gear shell-shaped gear case 8B meshes with the gear gear 7 when the buoyancy tank 2 is pulled down by its weight (this is i.e. after it has been filled with water) .The conversion, described above, is carried out according to the ebb or flow of the tide by the manual control of a handle 27 or by the use another suitable means of electrical control.

 The operation of the apparatus, which is the subject of this invention, will be described in detail as follows with reference to Figures 8A to 8E.

 Figure 81k shows the position of the four-way valve 12 when the buoyancy tank 2 of Figure 2 rises during high tide.

When the brake or pawl 30, as shown in FIG. 7, is released, triggered or released, the buoyancy tank 2 rises due to the buoyancy force which begins to move the rack 4 vertically by forcing the pinion 5 to rotate instantly by producing the force necessary for the operation or the drive of the pump 11 and then the force, for actuating the pump 11, is produced instantaneously.

At this moment, the converter apparatus 23 is in the position shown in FIG. 4 and the gear toothed wheel 7 meshes with the gear case in the form of a torso shell 8A which rotates both the shaft 8C and the pinion 10 as shown in FIGS. 2 and 4. Consequently, thanks to the operation of the pump 11, the sea water, contained in the buoyancy tank 2, is pumped into the upper tank 18 through the pipes 13 , 15. As a result, the water level in the buoyancy tank 2 is thus lowered, causing the buoyancy force to increase.

 When the buoyancy tank 2 reaches its highest position, it must stop. At this time, the water, previously pumped, falls through the conduit 20 and generates electricity by means of the generator E.

Meanwhile, the above water is collected or collected in the lower tank 17.

 FIG. 8B illustrates the case where the water, coming from the lower tank 17, flows into the buoyancy tank 2. As indicated in FIG. 3, when the buoyancy tank 2 reaches its highest position, the immersion or discharge valve 19 is opened by a suitable means controlled for example by an electric switch or switch as indicated in FIG. 9 and the buoyancy tank stops at a height or at a level which balances the weight of the tank buoyancy 2 and buoyancy force.

 At this time, the pinion 10 is blocked, immobilized or locked by means of a brake or pawl 30. Consequently, the buoyancy tank 2 remains suspended even at low tide. As a result, the plunge or discharge valve 19 is closed by means of an electrical switch and switch and the four-way valve is actuated or activated as shown in Figure 8B. The water from the lower tank 17 flows into the buoyancy tank 2, thereby increasing the weight of the buoyancy tank. Thus, the kinetic energy increases as a function of the increased weight of the reservoir. However before this moment, the converter apparatus 23 changes its state to pass from the position represented in FIG. 6A to the position represented in FIG. 6B thereby making it mesh the gear case in the shape of a torso shell 83 with the toothed gear wheel 7. FIG. 8C illustrates the position of the four-way valve when the water flows from the lower tank 17 into the buoyancy tank 2 and when seawater is pumped into the upper tank 18. During low tide, the brake or ratchet device 30 is released or released and the buoyancy tank 2 falls causing the rotation of the shaft 8C by means of the rack 4, of the pinion 5, of the gear cogwheel in the shape of a torso shell 83 and of the gear cogwheel 7. The shaft 8C in turn rotates the pinion 10 which drives the pump 11 connected to the pinion shaft 10. it follows that a force is instantly produced, so that the external sea water is pumped into the upper tank 18. FIG. 8D shows that it is only the external sea water which can be pumped through the pipes 15, 16. If the above-mentioned buoyancy tank 2 falls into the intermediate position, the four-way valve changes position to pass from the position shown in FIG. 8C to that shown in FIG. 8D, by means of an appropriate control means, for example electric and thus only pumps outside seawater.

 FIG. 8E illustrates the case where the conduits are in the closed or closed state. When the above-mentioned buoyancy tank 2 falls to its lowest position, the four-way valve occupies the position as shown in FIG. 8E. as a result, water is evacuated from the buoyancy tank when the immersion or discharge valve 19 is opened by an appropriate control means, so as to balance the buoyancy force of the buoyancy tank 2 with gravity , after which, the immersion or discharge valve 19 is closed.Then, the buoyancy tank is immobilized by the activation or 1Xengaging of the ratchet brake 30 and the converter device 23 changes state to pass from the position represented on the Figure 6B at the position shown in Figure 6A. At this point, the work cycle is completed. When the tide rises again, the brake or pawl is released by causing the buoyancy tank to rise and the four-way valve changes state to pass from the position represented in FIG. 8E to that represented in FIG. 8A. The production of electrical power is accomplished by repeating the above-mentioned work cycle.

Although this invention has been described in some detail and using several embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the scope of the invention. spirit of the invention. The invention is therefore not limited by the preceding description, but only by the claims which follow.

Claims (9)

 1.- Method for producing tidal electrical power, in which a buoyancy tank (2) comprises a buoyancy chamber (3) and a plunging discharge valve (19), and generates a buoyancy force and kinetic energy , characterized in that it consists in that the weight of the buoyancy tank (2) is controlled or regulated by regulating the water level in the buoyancy tank, in that the instantaneous force is produced by unlocking a brake or pawl (30) during the ebb and flow of the tide and in that the force, produced by the buoyancy force and / or by the kinetic energy, is constantly transmitted to a pump (11) by a toothed wheel gear in the form of a torso shell (8A, 8B), so that great energy can be obtained with little loss of energy.  2.- Method according to claim 1, characterized in that the brake or pawl (30) meshes with a pinion- (10) when the buoyancy tank (2) is balanced after the sea water and / or the water, contained in the buoyancy tank, has been pumped and the brake or pawl (30) is released during the ebb and / or flow of the tide.  3.- Method according to claim 1 or 2, characterized in that the control or adjustment of the weight of the buoyancy tank (2) is achieved by pumping water from the buoyancy tank (2) during the upward movement thereof and the flow of water from the lower tank (17) into the buoyancy tank (2) during the downward movement of the latter.  4.- Method according to one of the preceding claims, characterized in that it consists in modifying the position of a converter device (23) so that each gear tooth in the form of a torso shell (8A; B) is alternately caused to mesh with a gear toothed wheel (7) respectively depending on whether the movement of the buoyancy tank (2) is upward or downward.  5.- Method according to one of the preceding claims, characterized in that a four-way valve (12) is controlled so that the pump (11) pumps the water from the buoyancy tank (2) into an upper tank (18) during the upward movement of the buoyancy tank and the pump (11) pumps the external sea water into the upper tank (18> and said valve (12) releases the water from the lower tank (17) for qute31e flows into the buoyancy tank (2) during the downward movement of the latter.  6.- Method according to one of the preceding claims characterized in that a plunging discharge valve (19) is actuated dals the purpose of balancing the buoyancy tank (2) after the completion of the movement of this dsrrller.  tidal for carrying out the method according to one of the preceding claims, characterized by a power transmission device (22) comprising the converter device (23), the brake or pawl (30) and the four-way valve (12 ).  7.- Apparell electric power generator  8.- Apparatus according to claim 7, characterized in that the aforesaid converter apparatus (23) e consists of two gear wheels in the form of a torso shell (8A, 8B), one of which (8A) meshes with the gear gear (7) during the upward movement of the buoyancy tank g2) and the other (8B) meshes with said gear gear (7) during the downward movement of the buoyancy tank (2).  9.- Apparatus according to claim 7 or 8, characterized in that the four-way valve (12) is controlled so that the pump (11) pumps water from the buoyancy tank (2) into the upper tank (18 ) during the upward movement of the buoyancy tank (2) and the pump (11) pumps the external sea water into the upper tank (18) and said valve (12) releases the water so that it flows from the lower tank (17) into the buoyancy tank (2) during the downward movement of the latter.