FI124961B - Wave power - Google Patents

Description

wave power plant

The present invention relates to a wave power plant comprising two frame members which are movable with respect to each other, the first frame section being vertical and having a lower horizontal flange or other shaped body resisting up-down movement and the top being flat and perpendicular to the wave direction. , and the second body portion is floating horizontally and provided with a flange or fin or other shape piece transverse to the direction of wave propagation. This type of wave power plant is known from FR 2 858 667 A1 and US 200602322074 A1. The components connecting the frame members perform only reciprocating motion, which results in poor efficiency.

It has been difficult or impossible for known wave power plants to convert the wave motion into a continuous rotational motion with good efficiency. This conversion is particularly hampered by irregular wave motion and size variation.

It is an object of the invention to provide a new type of wave power plant in which the reciprocal motion of the waves is directly converted into a continuous rotational motion with good efficiency. This object is achieved by the invention on the basis of the features set forth in claim 1. Preferred embodiments of the invention are set forth in the dependent claims.

In the following, one embodiment of the invention will be described in more detail with reference to the accompanying drawing, in which

Figure 1 is a side elevational view of a wave power plant according to a preferred embodiment of the invention; and

Figure 2 shows a larger scale of the crankshaft area of the same wave power plant.

The wave power plant according to the invention is an ocean wave device which converts the energy of the waves into electrical or mechanical energy. A wave power plant converts wave motion directly into a rotational motion.

The wave power plant consists of two frame parts 1, 2 and a crankshaft 3 connecting them. From the crankshaft 3, power is applied to the desired device via a gear. Alternatively, the generator 6 can be placed directly on the crankshaft 3.

The vertical underwater hull section 1 of the power plant has a depth of about half the average wavelength of the region. The lower part of the body part 1 has a heavy horizontal plane or flange 4 or other shaped object which resists up-down movement. The planes or flanges 4 may be more than one and may have a shape other than planar, e.g. a spherical shape having a different flow resistance in opposite directions. If desired, a lateral directional flow control may also be used to provide a lateral force component. The upper part of the body part 1 is flat and perpendicular to the wave direction A of the wave. The function of the upper part of the body part 1 is to follow the horizontal movement of the wave. The total mass of the vertical frame 1, including the flange 4, is equal to the total mass of the vertical frame 1 and the flange 4.

The upright frame 1 is connected at its upper end by a crankshaft 3 transverse to the wave direction of the waves and connected to the floating horizontal frame part 2 of the power plant.

The horizontal body portion 2 is also about half or less than half the typical wavelength. At its opposite end to the crankshaft, there is a vertical fin or flange 5 or other shaped body transverse to the wave direction A which extends downwardly from the body portion 2 below the surface of the water. Naturally, the fins or flanges 5 may be more than one and may have a shape other than planar, e.g. a ballfish shape having a different flow resistance in opposite directions. If desired, a lateral flow control may also be used to provide a lateral force component. The fin or flange 5 pushes the body 2 in an opposite direction to the vertical body 1, the wave being at the fin or flange 5, generally at a position opposite to that of the vertical body 1. Due to the alternating buoyancy caused by the vertical motion of the wave, the end of the crankshaft 3 on the horizontal axis 2 moves up and down with an average quarter-turn phase difference with respect to the horizontal movement. Thanks to this arrangement, crankshaft 3 produces vertical and horizontal reciprocal forces which, due to their phase difference, cause the crankshaft to rotate. The rotational motion is synchronous with the fundamental wave. As a result, the wave power is resonant with the frequency of the fundamental wave, which improves the efficiency. The distance between the bearing lines of the crankshaft 3 is less than half the magnitude of the wave motion, for example 20-60% of this. Since the crankshaft, due to its size, does not allow full movement, a large rotating force is created on the crankshaft 3.

In an alternative embodiment of the invention, the distance between the bearing lines of the crankshaft 3 can be adjustable in such a way that the crankshaft 3 can be set to the desired stroke length. The distance between the crankshaft bearing lines can also be adjusted by a spring, either against spring force or by spring force. The necessary adjustment mechanisms and / or springs may be located in the shaft sections 3a between the bearing lines. The crankshaft 3 can be implemented in many ways in one or more parts. Essentially, it permits limited rotational movements of the proximal ends of the body members 1, 2, which at the same time rotate the crankshaft 3.

The power plant is anchored to the seabed by means of anchor cable 7 connected to the lower end of the vertical frame 1, which also has an electrical cable to the mainland. The device floats and seeks the right orientation for itself with the help of surface currents caused by wind and waves.

The flange or fin 5 of the horizontal body portion 2 may be heavier than the amount of water it displaces, but the lift of the horizontal body portion 2 prevents it from sinking. The levers of the body members 1, 2 are preferably dimensioned such that in calm water the bearing lines of the crankshaft 3 are substantially aligned. The crankshaft may be partially or completely above the water surface during operation.

The power take-off is arranged on the second bearing line of the crankshaft 3 on a rotary shaft.

The distance of the flange or fin 5 of the horizontal body 2 from the crankshaft 3 may be adjustable. Also, the distance of the flange 4 of the vertical frame member 1 from the crankshaft 3 can be adjustable. In this case, the device can be easily converted to function optimally under various wind and wave conditions.

The wave power station preferably includes a computer controlled crankshaft 3 speed compensator. The large variation in the speed of rotation of the crankshaft 3 under some wave conditions can be a problem. A large wave will cause a rush that may be in the wrong position with respect to the crankshaft position and the next wave. The computer-controlled RPM monitors the crankshaft rotation speed and allows it to vary within a set range, e.g., up to 5% RPM. If the rotation speed tends to increase faster than set, the automation will increase the generator resistance. If the rotational speed tends to fall faster than specified, the resistance of the generator 6 is reduced or even increased by the rotation speed of the crankshaft 3 by supplying energy to the generator.

Thanks to the speed compensation system, the rotation of the power plant's rotating parts is smoother and more continuous. There are no stops and, consequently, energy production is also increased.

Alternatively or additionally, the flywheel can be used as a speed equalizer. The massive, fast-rotating flywheel connected to the crankshaft via a gearbox can be used to compensate for speed variations in the same way as the aforementioned computer-controlled speed compensator. The generator 6 may be connected to a flywheel which may be housed in the same housing as the generator 6. The gears can be infinitely adjustable and the automatic can take care of the gear ratio so that sufficient crankshaft 3 speed compensation is achieved.

Also, the phase angle of the crankshaft 3 with respect to the movement of the body parts caused by the waves is advantageously optimized by computer control. A computer controlled phase angle optimizer is a system that monitors the phase angle of a crankshaft relative to the motions, accelerations, and forces between the power plant hulls and seeks to keep the phase angle at an optimum average. In terms of energy production, it would be most advantageous if the ends of the body members at the axis lines tend to move substantially perpendicular to the plane passing through the axis lines. In this case, the maximum torque of the crankshaft 3 is reached. The Phase Angle Computer Optimizer may also receive pre-information from an incoming wave at a predetermined distance from the wave height or acceleration sensor / sensor positioned in the forward direction of the wave in front of the device.

All of the functions disclosed relate to the rotation of the crankshaft 3 caused by the movements of the body members so that they either promote the movement of the body parts generated by the waves or independently convert the motion of the waves into the motion of the body parts. Thus, various combinations of the functions described may be used, or all functions may be utilized in a single floating power plant. The functions described will provide a stable and highly profitable power station.

The desired power can be obtained for the power plant by selecting a suitable width. The length, depth and crankshaft 3 dimensions of the device are determined by the typical wave dimensions of the region. Naturally, several power plants can be placed side by side and in succession.

Claims (10)

1. A wave power plant, to which it belongs two mutually constrained body parts, of which the first body part (1) is vertical and in its lower part is a heavy horizontal flange (4) or another molding which opposes an upward-downward movement and the upper portion is flat and perpendicular to the incoming direction (A) of the wave, and the second body portion (2) is horizontally liquid and provided with a flange or fin (5) or other molding which is transverse to the incoming direction (A) of the waves, characterized in that the body parts (1, 2) are joined to one another by a crankshaft (3), to which the body parts (1, 2) are joined by bearings whose bearing lines are at a distance from each other, and that the distance of the mold pieces (4, 5) from the crankshaft (3) has been chosen in relation to the wavelength of the essential wave so that the wave movement causes the continuous rotation of the crankshaft (3) in one direction. Wave power plant according to claim 1, characterized in that the distance between the bearing lines of the crankshaft (3) is adjustable or regulated against spring force or by means of spring force. Wave power plant according to claim 1 or 2, characterized in that the distance of the crankshaft (3) from the flange or fin (5) of the horizontal body part (2) is about half of a typical wavelength. Wave power plant according to any one of claims 1-3, characterized in that the distance of the crankshaft (3) from the flange (4) of the vertical body part (1) is about half or at half the length of a typical wave. Wave power plant according to any one of claims 1-4, characterized in that the joint lifting force of the vertical body part (1) and of the associated flange (4) is substantially equal to their mass. Wave power plant according to any one of claims 1-5, characterized in that the flange or fin (5) of the horizontal body part (2) is heavier than the amount of water it displaces, but the lifting force of the horizontal body part (2) prevents it from sinking. 7. A power plant according to any one of claims 1-6, characterized in that the power take-off has been arranged with the shaft rotating on the second bearing line of the crankshaft (3). Wave power plant according to any one of claims 1-7, characterized in that the distance of the flange or fin (5) of the horizontal frame member (2) from the crankshaft (3) is adjustable. Wave power plant according to any one of claims 1-8, characterized in that the distance of the flange (4) of the vertical body part (1) from the crankshaft (3) is adjustable. 10. A wave power plant according to any one of claims 1-9, characterized in that the rotational movement of the crankshaft (3) is synchronous with the period of a substantial wave, the wave power plant acting in resonance.