FR3121185A1 - System for generating electricity from sea waves - Google Patents

Abstract

It is a system for producing electricity from the waves of the sea. We used the lever system to be able to recover the power of the waves from a height of 50cm. up to 5.50m. In fact, a giant buoy will push a frame upwards as the waves pass. The chassis is fixed at one end by an axis around which it can pivot freely, at the other end is fixed a rack in the shape of an arc of a circle, which will turn 2 pinions connected to 2 freewheels. The first recovers the force resulting from the rise of the waves, and the second recovers the force of the weight of the frame when the wave passes. The continuity of these 2 forces causes a continuous force which, amplified by a gearbox, will rotate a shaft (output shaft) at a speed of 1500 rpm. A current generator will convert this mechanical energy into electricity. Figure for abstract: (Fig 12)

Description

System for generating electricity from sea waves

Take a good look at the sea, the ocean, this mass of water always in motion. Sometimes gentle, sometimes less calm, sometimes slightly agitated and rarely very very agitated (during storms), but always in action. Looking closely at the force of the waves shaking the small boats of the fishermen and how they move in the open sea, we think how to recover this power which lifts all this mass of water in the form of waves and which never stops, day and night. Can we use this force and make it beneficial?

How to recover the movement of the waves, rigorous, powerful, incessantly, and transform it into a force as rigorous and beneficial for Man, this natural, non-polluting and renewable power, produced 24 hours a day and 7 days a week? Sometimes the movements are small, waves that make an up and down movement that do not exceed half a meter in what is called a calm sea, sometimes medium movements, or even a moderately rough sea, waves ranging up to 4 meters, Sometimes strong movements or strong seas therefore very high movements forming waves of height up to 12 m in the oceans. Not to mention storms, and uncontrollable movements.

Note that waves transmit energy. Our goal is to capture this energy, very important, renewable, free without the slightest cost, and make it useful, while using natural and theoretical bases of the mechanisms of fluids and solids.

MOWEC, M echanical O cean W aves E nergy C onverter, is a new system for generating electricity from sea waves.

(To see )

Note: all gears are helical type

Preliminary study

In this study, we first sought to dominate the random and horizontal forces. These very delicate forces can direct the power transmitted by the waves in an undesirable direction. We decided to use 4 vertical cables that cross the buoy vertically. These cables will limit the movement of the buoy in a direction and a well-determined course of action.

This machine was created to use 2 well-known theories of vertical forces:

1. The Archimedes thrust vertical force upwards, it is translated by the passage of the waves and the rise of the water, which will exert a force on the buoy and pushes it upwards. The buoy on its side will push the structure upwards.
2. The downward force of gravity, represented by the weight of the structure after the wave has passed, which will in turn exert a downward force.

According to the thrust of Archimedes, the floating body will easily push the structure, which represents a large arc with a toothed end, forming a round rack, upwards when the wave arrives, and then, when it passes, the force of gravity will push vertically downward.

Then we thought of amplifying the vertical movement of the waves when the sea is calm to facilitate the transfer of the power transmitted by the small waves. The lever system will help solve this problem. Indeed, the arc fixed on one side by its axis, the thrust of a wave of 50cm. in the middle of it, which represents the converter of the horizontal movement in rotary movement, will cause a movement of a little more than 100 cm at the end of the arc, at the level of the rack. This facilitates the recovery of the transmitted power. The amplification of movements will be reduced according to the power of the waves.

To be able to operate for more than 98% of the time, in various environments, we were able to establish 3 different machine sizes:

1. Small size: for wave heights between 50cm and 235cm.
2. Average size: Wave height between 1.5m. and 5.5m.
3. Large size: Wave height between 4m. and 12m.

Size calculation tables will be attached at the end.

Indeed, our system is composed of 5 main elements:

1. The floating body

Of a fairly large volume and very rigid. The volume, dimensions and shape of the buoy will be chosen so as to capture the maximum of movements, and therefore of power, for a given wave height margin. It will be installed on a support fitted with 4 fairly thick vertical steel cables to stabilize the oscillatory movement of the latter, and to keep it moving in a well-defined vertical plane. These cables will be fixed on a sliding board under water at the bottom and at the top, by wheels which move on 2 bars above the complete system. The board moves between the middle of the chassis and its right end through a moxon vice fitted with an automatic system to make it move to the right or to the left depending on the speed of rotation of the axis that comes out of the gearbox. (To see )

This system will make it possible to move the plane of action of the float along the arc. In other words, this displacement will be carried out according to the height of the waves. That is, when the waves are low, the floating body will be moved to the middle. This will amplify the action of the waves. When the waves are higher, we move the body to the right. This principle makes it possible to dominate a large margin of wave height. Beyond a height determined by the dimensions of the system, the whole system must be protected, and the floating body too.

1. The frame or the bow.

It is the element that will convert the vertical oscillatory motion into continuous rotary motion. It has the shape of an arc of a circle equipped with a rack. On one side is the axis around which the frame will rotate. On the other side is fixed, in the form of an arc, a helical rack 14 cm wide. The latter is linked to the axis by 5 rigid bars in the shape of the radii of a circle. These bars are linked together and reinforced with oblique bars to maintain their arrangement and improve the rigidity of the frame. (See diagram) This chassie will rotate two pinions connected to 2 different axes and aligned. They represent the input of the force in relation to the gearbox.

(To see )

This makes it possible to recover the force caused by the rise of the waves on the one hand, (Archimedean thrust), and the force resulting from the weight of the frame which descends on the other hand, (Force of gravity).

This chassis will be equipped with an automatic system that will allow it to be fully raised during storms to protect it. This security system will be triggered automatically or by the monitoring service in the event of a failure.

1. The push bar.

This is the system that transmits the force recovered by the buoy to the frame. Completely integrated and fixed to the bottom of the buoy, it translates the force recovered from the waves by a vertical and powerful thrust upwards. It is linked on the 4 sides to the cables which hold the buoy by means of 4 rods at the end of which are fixed 4 rings which slide along the cables and which always leave it in a vertical position. It is quite long and can almost reach the middle of the frame. It is made of 2 very thick iron bars and passes on either side of the chassis. At the end of these 2 bars and on the inner side will be fixed 2 other bars (arms) by means of 2 linear axes. These will link the push bar to a sliding lever along the lower bar of the chassis. They will move to the right and to the left following the handle firmly fixed to the chassis. The joystick moves along the lower axis of the chassis using a moxon vice. The movement of the joystick and that of the sliding board will be well synchronized, which makes it possible to have the joystick and the buoy always in the same field of work. A system of teeth on the upper part of the handle and the lower part of the frame will help to fix them when the waves push.

(To see )

1. The gearbox (gearbox)

Two pinions whose teeth come out of the box are the entry points of the action. They are mounted on 2 different axes but aligned. The first will turn another pinion, smaller, mounted on the same axis. The latter equipped with a chain which will turn a free pinion mounted on a long axis parallel to its axis on the right side. Similarly, the second pinion turns another pinion, which will turn another pinion of the same size mounted on an axis parallel above its axis. This last pinion will turn in the opposite direction to the main pinion. It will in turn turn a chain sprocket identical to that of the first sprocket. The chain will turn a free sprocket mounted on the same major axis. We will therefore have the first pinion transmits the force when it turns upwards, (Archimedean thrust) and the second transmits it when it turns downwards (force of gravity). On the main axis we have fixed on both sides 2 heavy wheels in order to have a regular rotation, and in the middle, another toothed wheel whose diameter is 30cm. The result of all the forces will be transmitted by this large toothed wheel in the same direction. The latter will turn a pinion 10cm in diameter mounted on an axis parallel to the right. This pinion in turn turns a cogwheel which will turn the final axis. We must have a final rotational speed of 1500 rpm.

(To see )

1. Framing :

It is the metal structure that will maintain the function of each element of the system and that will facilitate its function. Fixed to the bottom of the sea, at a depth adapted to its size, it must rise very high to dominate and protect the whole system. It will strengthen the links created between the different elements, strengthen its positions, and control their actions. It will facilitate the transmission of power from one element to another following the well-defined course. She will fix the axis of the chassis and let it pivot around him. She will rigorously maintain her action plan. Additionally, using rods and bearings on either side of the bow will help it resist the wind. On the other side, the frame will fix the link between the rack of the arch and the input pinions of the gearbox, and then between the final axis of the latter and the generator.

In addition, the tower has the bars that hold the 4 ropes and the sliding board that stabilizes the action plan of the buoy.

(To see )

System overview

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The list of new elements to be patented

1: ARC

(To see )

The arch is a large rack in the shape of an arc of a circle which pivots around an axis. It is used to translate vertical motion into rotary motion.

The bottom side of the frame is toothed like the top side of the handle, to prevent slipping.

2: The buoy operating system

(To see )

The buoy is of large volume. It will capture the energy transmitted by the waves and translate it into an upward thrust. The push arm is always in a vertical position, will be equipped with an arm that will carry the joystick and move with it.

The 4 cables will stabilize the vertical movement of the buoy and eliminate small horizontal jolts, therefore channeling the force in one direction.

The Moxon 1 vise will move the joystick right and left depending on the height of the waves.

The Moxon 2 vise takes care of the board that holds the buoy cables. It will move the action plan of the buoy according to the position of the joystick.

3: The gearbox.

(To see )

Two pinions whose teeth come out of the box are the entry points of the action. They are mounted on 2 different axes but aligned. The first will turn another pinion, smaller, mounted on the same axis. The latter equipped with a chain which will turn a free pinion mounted on a long axis parallel to its axis on the right side. Similarly, the second pinion turns another pinion, which will turn another pinion of the same size mounted on an axis parallel above its axis. This last pinion will turn in the opposite direction to the main pinion. It will in turn turn a chain sprocket identical to that of the first sprocket. The chain will turn a free sprocket mounted on the same major axis. We will therefore have the first pinion transmits the force when it turns upwards, (Archimedean thrust) and the second transmits it when it turns downwards (force of gravity). On the main axis we have fixed on both sides 2 heavy wheels in order to have a regular rotation, and in the middle, another toothed wheel whose diameter is 30cm. The result of all the forces will be transmitted by this large toothed wheel in the same direction. The latter will turn a pinion 10cm in diameter mounted on an axis parallel to the right. This pinion in turn turns a cogwheel which will turn the final axis. We must have a final rotational speed of 1500 rpm.

Note: All sprockets are all helical type.

4: The complete system.

(To see )

Nomenclature.

1. Rigid metal structure.
2. Power generator.
3. Gearbox
4. rack
5. Base of action (mobile).
6. Action transmission axis.
7. 4 cables fixing the action plan.
8. The buoy
9. Sliding board that modifies the action plan of the buoy.
10. Chain transmitting the force of gravity.
11. Gearbox output shaft.
12. 2 free sprockets mounted on the same axle.
13. 2 heavy regulating wheels.
14. Chain transmitting the thrust of Archimedes.
15. Arm.
16. Controller.
17. Chassis fixing teeth.
18. Joystick teeth.
19. Controller fasteners.
20. Attachment to the bottom of the buoy.
21. Fixator on the top of the buoy.
22. Helical rack.
23. The axis.
24. Moxon 1 vice to move the joystick.
25. Gear rack and action input pinions in the gearbox.
26. Moxon 2 vice to move the cables fixing the buoy.
27. Sprockets, cogwheels and axles to speed up the rotation.
28. Left-hand 20-tooth free chain sprocket.
29. Free chain sprocket 20 teeth on the right.
30. 2 chain sprockets 40 teeth.
31. ^1st action input pinion.
32. 2nd action ^input gear.
33. 2 toothed wheels of the same size to reverse the direction of rotation.
34. Fixing cables.
35. The arm that holds the controller.
36. The pushing arm.
37. Moxon 2 vice to move the buoy.
38. 2 heavy duty speed regulating wheels.

Claims (6)

A machine for converting sea wave energy into mechanical energy for power generation system. It is a machine for the mechanical conversion of the power carried by the waves of the sea into mechanical energy represented by a rotational force of a shaft (output axis) suitable for a current generator which transforms it into electrical energy. Based on 2 theories of vertical forces: Archimedes' thrust and the force of gravity, it will transform the oscillatory motion of sea waves into rotary motion. He understands :

• The floating body is a large buoy, which according to Archimedes' theory will push the frame upwards when the wave arrives.
• A frame representing on one side a rack in the shape of an arc of circle which pivots around an axis fixed to the other side.
• A push bar attached to the bottom of the buoy will pass the action of the buoy to the frame. It is linked to an arm which is in turn linked to a sliding lever along the lower frame bar.
• A gearbox having 2 action input gears and an output shaft which provides the resulting action. The first pinion transmits the force when the rack moves up and the second transmits the force when the rack moves down.
• A rigid frame will be fixed to the bottom of the sea. It will fix the axis of the frame and protect its operation. In addition it will maintain the gear between the rack and the 2 gears of the gearbox.

A machine for converting the energy of sea waves into mechanical energy for an electricity production system according to claim 1 characterized in that the buoy is crossed by 4 vertical cables to annihilate the horizontal jolts and stabilize the vertical oscillations . These cables are fixed at the bottom on a board which moves through a Moxon vice. A machine for converting the energy of sea waves into mechanical energy for an electricity production system according to claim 1, characterized in that the frame is used to rotate the two input pinions of the gearbox and translate vertical motion into rotary motion. A machine for converting the energy of sea waves into mechanical energy for an electricity production system according to claim 2 characterized in that a Moxon vice installed on the handle makes it possible to modify the position of the handle on the chassis. A machine for converting the energy of sea waves into mechanical energy for an electricity production system according to claim 1, characterized by a gearbox as follows: Two sprockets whose teeth come out of the gearbox are the points of action entry. They are mounted on 2 different axes but aligned. The first will turn another chain sprocket mounted on its axis. The latter equipped with a chain which will turn a free pinion mounted on a long axis parallel to its axis on the right side. On the other hand, the second pinion turns a toothed wheel mounted on its axis, which will turn another toothed wheel of the same size mounted on an axis parallel above its axis. The latter will turn in the opposite direction to the main gear. It will in turn turn a chain sprocket mounted on its axis and identical to the first chain sprocket. The chain will turn a free sprocket mounted on the same major axis, but which pushes in the opposite direction to the other. We will therefore have the first pinion transmits the force when the frame goes up and the second transmits it when the frame goes down. On the main axis we have fixed on both sides 2 heavy wheels in order to have a regular rotation, and in the middle of the axis, we have installed another toothed wheel which will receive and transmit the result of all the forces, which now push in the same direction, and then it will turn a smaller pinion mounted on a parallel axis to the right. This pinion in turn turns a cogwheel which will turn the final axis. The rotational speed of the shaft (output shaft) is 1500 rpm. A machine for converting the energy of sea waves into mechanical energy for an electricity generating system according to claim 5 characterized in that all the pinions are all of the helical type.