DE19615115A1 - Wave-powered power generation plant - Google Patents

Abstract

The energy generation plant has at least one body (2) which is moved by the wave movement relative to a second body (1), which remains stationary, or which only moves slightly in response to the wave movement, with mechanical conversion of the relative movement into useful energy. The stationary body can be provided by a floating core of large mass, provided around its periphery with a number of lightweight floats displaced by the wave movement for operation of compressors via respective crank rods (4). Components for extraction of electrical energy and hydrogen/oxygen may be incorporated in the plant.

Description

The invention relates to a wave power plant. They are different bodies Weight or different shape associated with each other such that they, swinging in the waves, have a different vibration behavior develop around a common horizontal axis. The path of force that emerges from the amplitude difference from heavily moved to moderate, not or bodies moving in opposite directions is obtained by means of mechanical Power transmission between the bodies made usable and storable Converts energy sources.

Such a device is not known.

The invention has for its object to a wave power plant develop, which is an environmentally friendly production of storable energy made possible by wave power.

According to the invention, the object is achieved in the wave power plant in that that vibrations from the waves of moving bodies, which are articulated with less moving parts of the system are connected by means of mechanical Power transmission converted into another form of energy, and thus usable be made. The height differences of the waves, or the inclination of the Wave edges, trigger movements of buoyancy bodies. This Vibrations are mechanically generated on generating units for storable energy sources passed on to the moderate, not or counter-vibrating system parts are installed.

The basic idea of the invention is the energy of Sea waves in economically usable, environmentally friendly forms of energy like converting compressed air, electricity and hydrogen / oxygen, which can be used arbitrarily.

The main advantages of the invention are that the clean Energies electricity and hydrogen / oxygen through the clean Energies wave power and compressed air are generated. A feed of Raw materials for energy production is not necessary and it will fall minimal emissions due to maintenance measures only.

The power plant consists of a buoyant construction, which on Anchored to the sea floor, or on a buoyant or stationary Central unit is movably attached. It has the shape of at least one Floating body, which is shaped so that the local Waves set him in vibration. This buoyancy body is with a second body with missing, different or staggered Amplitude mechanically connected in such a way that a usable force path arises between the bodies.  

The one with the swell around a constructively determined horizontal The transverse axis of the floating body is in this axis with a second body movably connected due to its shape and Placing as high a persistence as possible, or even a opposite vibration behavior. The one through the different amplitude of the two bodies of force path implemented in work by means of a mechanical power transmission.

To illustrate the principle, both the touch of two ships of different sizes in high seas, as well Serve the cargo slipping on a lurching ship. In both In some cases there is a resting mass (large ship, cargo) of a moving mass (small ship, hull) opposing, immense forces to be released. The same effect occurs when a ship is in moving sea rises high above a fixed obstacle, and then up this falls down. The harnessing of this natural energy is that Purpose of this invention.

Design of wave power plants up to the extraction of compressed air:
In the first embodiment of the invention, the working buoyancy bodies are arranged around a tube made of steel or concrete floating vertically in the water or standing on the sea floor in such a way that they can be lifted by the incoming waves. The buoyancy bodies are connected to the tube by means of a joint piece in such a way that the resulting stroke is transmitted to a connecting rod. The connecting rod actuates a two-way compressor that compresses air both under pushing and pulling force and presses it into a reservoir.

In a further embodiment, a row is at a suitable distance tubes floating vertically in the water from each other through beams suitable material and joints with a horizontal axis of rotation connected that the beams in the swell pressure and tension on connecting rods exercise. The anchoring point on the narrow side enforces the ideal alignment of the system when the flow starts.

In a further embodiment of the invention, the power plant consists of pontoons articulated to each other when waves are passing Carry out pitching movements around the horizontal axis. The resulting one The shear movement of the pontoon axes against each other is increased by means of linkage the compressor connecting rods transmit. The one attached to the narrow side Anchoring point enforces the ideal alignment of the system starting flow.

In a further embodiment of the invention, the power plant consists of horizontally articulated floating bodies, being a inner, bow-shaped body of a catamaran-like frame is enclosed, the long sides of which are designed as floating bodies. The front and rear sections of the frame are kept open, thus enabling the entry and exit of the waves that move the inner float, which acts on the connecting rods. The frame with the side  Floats and the compressor remains its shape and due to its own weight in a relative rest position, or even by means of of a baffle under the waterline particularly deep in the wave drawn in. The one on the narrow side facing the incoming waves attached anchor point forces the ideal alignment of the system.

In a further embodiment of the invention, the power plant consists of one elongated, or two horizontally rigidly interconnected Floats, in or on which a pendulum-like around the horizontal Transverse axis vibrating mass is installed so that it by means of a mechanical power transmission can actuate a compressor, which is in or on the system. The one on the narrow side attached anchor point forces the ideal alignment of the system when the current starts.

The invention consists of the aforementioned elements, the, by which Difference in amplitude of a mass moved by waves to one entirely or relatively unmoved mass, convert the resulting force path into work. The change in the inclination of the mass axes due to the swell each other is converted into compressed air by means of compressors. The Stored compressed air can be stored in a turbine or a motor Electricity can be implemented, which in turn is extraction and Storage of hydrogen / oxygen enabled.

Both single and multiple wave power plants can be combined be used.

The compressed air can be generated both in the wave power plant and externally be converted into other forms of energy or carriers.

The usable energy generated can be stored in the wave power plant and / or directed to an external recovery agency.

Embodiments

• 1. The necessary components are in the wave power plant Compressed air generation housed. The compressed air is used externally.
• 2. The necessary components are in the wave power plant Compressed air generation and storage as well as for electricity generation housed. The electrical current is used externally.
• 3. The necessary components for compressed air are in the wave power plant electricity and hydrogen / oxygen generation housed. hydrogen and oxygen are sent to an external recycling center.
• 4. In the wave power plant are all components, including the Hydrogen-oxygen storage.

Exemplary embodiments are explained in more detail with reference to the drawings. It demonstrate:

Fig. 1 A floating wave power plant in tubular form in a side view.

Fig. 2 A floating wave power plant, consisting of three vertical tubes, which are connected to one another by means of cross members and joint pieces such that the shear force of the carrier is transmitted to compressors by means of connecting rods.

Fig. 3 A floating wave power plant, consisting of two balls or horizontal tubes, which are rigidly connected to each other by carriers. In the partial sectional view, the pendulum-like vibrating mass is shown, which acts on the connecting rod.

Fig. 4 A floating wave power plant, consisting of two articulated buoyancy bodies, of which the outer catamaran-like, the other hand is shaped like a bow, in side view and top view.

Fig. 5 The components of Fig. 4 in an individual representation.

The following reference numerals have been used in FIGS. 1 to 5:

1 low amplitude buoyancy body
2 floating bodies with strong amplitude
3 hinge between the floats
4 connecting rod
5 compressor room / compressor
6 Direction of work performance in relation to the swell
7 waterline / swell
8 intake manifolds
9 anchor point
10 baffle
11 beams / struts
12 flywheel / pendulum, movable about the horizontal axis.

Explanations to FIGS. 1 to 5 Fig. 1

A floatable vertical tube ( 1 ) of large mass is shown, which serves as an assembly support. At the level of the normal water line, buoyancy bodies ( 2 ) are installed, which are connected to the tube in an articulated manner by means of a horizontally attached hinge ( 3 ) and move the connecting rods ( 4 ) up and down to the compressors in waves. Outside the tube, the compressors for generating compressed air are accommodated in a rotating hollow body ( 5 ). The compressor room is largely sealed against the impact of waves; the air supply for the compressors takes place via suction lines ( 8 ) which extend beyond the tube.

The floating version of the wave power plant is by suitable Ballast held at the bottom of the tube in the vertical and is per Chain anchored to the ocean floor. (not shown).

The wave energy is used in such a way that the buoyancy bodies ( 2 ) are raised by a wave that is starting up, while the vertical tube ( 1 ) remains in a relative rest position due to its greater inertia and its smaller contact surface. The lifting movement is transmitted to the piston of the compressor ( 5 ) by means of a connecting rod ( 4 ), which generates compressed air depending on the height and length of the shaft. If the shaft has passed under the buoyancy body, it sinks into the trough and pulls the compressor piston in the opposite direction due to its own weight. Compressed air is also generated in this phase.

To Fig. 1 (without picture)

The permanently installed variant of the wave power plant stands on a foundation on the sea floor, whereby the buoyancy bodies ( 2 ) and the compressor chamber ( 5 ) are designed to be height-adjustable together in order to achieve optimum efficiency at any water level. The compressed air generating unit is placed on suitable rails or moved up the tube, depending on the water level.

The wave energy is used in such a way that the buoyancy bodies ( 2 ) are raised by a wave that is approaching. The lifting movement is transmitted to the piston of the compressor ( 5 ) by means of a connecting rod ( 4 ), which generates compressed air depending on the height and length of the shaft. If the shaft has passed under the buoyancy body, it sinks into the trough and pulls the compressor piston in the opposite direction due to its own weight. Compressed air is also generated in this phase.

Fig. 2

Three floatable bodies of large mass ( 2 ) are connected to one another by means of cross members ( 11 ) and joint pieces ( 3 ) in such a way that they can move independently of one another in the vertical. The height differences caused by the wave movement ( 7 ) cause a shear movement of the carrier against the floating bodies, which is transmitted to the floating bodies by means of connecting rods ( 4 ) to compressors ( 5 ).

Fig. 3

Two hollow buoyancy bodies ( 2 ) are connected to each other horizontally by means of suitable supports ( 11 ) and equipped with compressors ( 5 ) on their upper side. A mass of high weight ( 12 ) is suspended in a pendulum-like manner in the buoyancy bodies and connected to the compressor via a connecting rod ( 4 ) in such a way that compressed air is generated with each movement of the unit. Due to the anchoring at the attachment point ( 9 ), the unit is inevitably oriented in such a way that each incoming wave and also each wave trough raise or sink the two bodies ( 2 ) one after the other. The resulting pitching movement ( 6 ) of the buoyancy bodies around the horizontal transverse axis becomes, due to the tendency of the pendulums to align themselves vertically, a force path which is implemented in work via the connecting rods.

FIGS. 4 and 5

A catamaran-like buoyancy body ( 1 ) encloses a buoyancy-like buoyancy body ( 2 ) and is connected to it on the narrow side in such a way that the two bodies can move in opposite directions about the horizontal axis of the joint. The catamaran-like body ( 1 ) offers little resistance to the incoming wave, so its position remains relatively stable. The inner buoyancy body ( 2 ), on the other hand, is attacked by the water over a large area and rises through buoyancy and current in the frame surrounding it. The different amplitudes of the two floating bodies, which form an articulated unit, are converted into compressed air by a connecting rod and a compressor. The effect is reinforced by the baffle plate ( 10 ), which forces an additional downward movement of the outer buoyancy body when it flows against the shaft, while at the same time the inner buoyancy body rises unimpeded on the crest of the shaft.

Further advantageous embodiments of the invention are in the Claims set out.

Claims (16)

1. wave power plant, characterized in that between a strong in the waves and a little, not, or moving counter-moving buoyancy, force path is converted into a usable form of energy by means of mechanical power transmission. 2. Wave power plant according to claim 1, characterized in that a floating core of large mass movable around Buoyancy bodies are arranged, which are connected by connecting rods Compressors act, and the entire system is buoyant. 3. wave power plant according to claim 1 and 2, characterized in that the movable buoyancy bodies around you firmly on the ocean floor standing core are attached around. 4. wave power plant according to claim 1 to 3, characterized in that Shape components to generate additional energy, especially from Electricity and hydrogen / oxygen are integrated. 5. wave power plant according to claim 1 to 4, characterized in that each of the usable energy generated forms a by means of a line external storage or recovery is supplied. 6. wave power plant according to claim 1 to 5, characterized in that several plants for the production of compressed air, electricity or Hydrogen / oxygen through lines with a common Central unit for storing these energy sources are connected. 7. wave power plant according to claim 1 to 2 u. 4 to 6, thereby characterized in that several floating plants for the production of Compressed air, electricity or hydrogen / oxygen, as well as a Floatable central unit for the storage of compressed air, generation of Electricity and / or hydrogen / oxygen, as well as for the storage of Hydrogen and oxygen, connected by a frame are. 8. wave power plant according to claim 1 to 2 and 4 to 6, characterized characterized in that several plants for generating compressed air, Electricity or hydrogen / oxygen using cross beams and Joint pieces are connected to each other in such an articulated manner that at Waves a shift of the carrier axes against the axes of the A buoyancy body, i.e. a force path, is created which is connected to the connecting rod and Compressors is converted into usable energy.   9. wave power plant according to claim 1 and 4 to 7, characterized characterized in that a bow-shaped buoyancy body and a Catamaran-like float on one of the narrow sides like this are articulated with each other so that the bow-shaped body within the catamaran-like body freely around the horizontal Joint axis can swing. 10. wave power plant according to claim 1 and 4 to 7, characterized characterized that two buoyancy bodies, which, by swell conditioned pitching movements around a pendulum-like mass Execute weight, connected to each other by means of a rigid frame are. 11. wave power plant according to claim 1 and 8 to 10, characterized characterized in that flow baffles attached at a suitable location increase the pitching movements of the buoyancy bodies. 12. wave power plant according to claim 1 and 8 to 11, characterized characterized in that the attachment point of the anchorage to that Side of the system is located, which face the incoming waves should. 13. wave power plant according to claim 1 to 2 and 4 to 12, characterized characterized that the system by means of steel cable, chain or linkage is movably anchored on the sea floor. 14. wave power plant according to claim 1 and 8 to 11, characterized characterized in that a vertically attached at a suitable point spindle-shaped weight keeps the anchor rope or chain taut, according to Alignment of the system favored against the incoming waves, and Reduces peak loads on the anchor fasteners. 15. wave power plant according to claim 2 to 10, characterized in that the compressor housings are installed so that they are protected from sea water washed around, so cooled. 16. Wave power plant according to claim 1 to 14, characterized in that the resulting force path via chains, gears or steel cable to an in flywheel installed with a compressor or a generator is coupled, is transmitted and their angular momentum reinforced.