DE3909151A1 - Wave power installation utilising the kinetic energy of water waves, in particular the energy from horizontal travelling wave motion, for driving generators or pumps - Google Patents

Abstract

In the already known wave power machines, the kinetic energy of the sea waves predominantly from the vertical reciprocal motion of the waves is used for the purpose of conversion into consumable energy (current). This possibility requires a complicated mechanical system and can be applied economically only to a restricted extent. The novel wave power installation provides for obtaining the consumable energy from the horizontal travelling motion of the sea waves. This possibility operates according to a simple, tried and tested principle and can be implemented economically on a large scale. The operating principle of the wave power installation is based on the driving (rotary movement) of bladed (bucket) drum type (barrel) wheels, conveyor screws (screw conveyors) or propeller screws by the kinetic energy of the water waves. In order to compensate the waxing and waning wave energy, the drive elements are coupled to torque convertors (flywheels) and are arranged at a spacing and offset in the direction of wave travel. The wave power installation is designed with a variable level and capable of rotating for the purpose of adaptation to the wave level and the wave direction. The aim of the wave power installation is to make use of the gigantic energy potential of sea waves for consumable energy. A single sea wave with a width of 100 m contains a quantity of water of 15000 m<3> in round figures for a moderate sea and has a speed of approx. 12.5 m/sec, which corresponds to a kinetic energy of 1171875 kJ.

Description

The invention relates to a wave power plant with off use of kinetic energy from water waves, especially the energy from the horizontal world oil movement to drive generators or Pump.

Such wave power plants can help Consumption energy (electricity) from the inexhaustible, high-performance energy potential of ocean waves, without preparation, environmentally friendly, harmless, without waste products, after a proven work principle, low maintenance, inexpensive and economical win.

To meet these requirements, wave force Machines known (German Patent No. DE 30 17 257 A1, DE 30 44 198 A1, DE 31 33 726 A1, DE 32 15 486 A1), which uses a mechanical system kinetic energy from the vertical lifting movement or in combination with the horizontal barrel Allow movement of ocean waves.

These possibilities of using energy are necessary complex mechanics and can only be used in limited dimensions can be implemented economically.

The invention is based, Ver energy consumption from the horizontal running movement of the Sea waves according to a proven, simple, mecha principle, economically and to a large extent win.  

This object of the invention is achieved in several Generic facilities by the kenn Drawing features of claim 1 solved.

The advantages achieved with the invention exist especially in that the wave power plant by an appropriate structure and mode of operation, as well the possibility of continuous adjustment to the water wave level and the water wave rich tion and through the use of proven drives elements, such as bucket roller wheels, screw conveyors or propeller screws in connection with torque converters, gears, generators, pumps, one host economic exploitation of the kinetic energy the horizontal movement of the ocean waves in large dimensions and enables.

Several embodiments of the invention are in the drawings and are shown below described in more detail.

Show it

Fig. 1, 2 u. 3 a wave power plant with front, top and. Side view, partly cut,

Fig. 4, the working principle of a wave power plant in an isometric projection,

Fig. 5, 6 u. 7 another version of a wave power plant with front, top and. Side view, partly cut,

Fig. 8 u. 9 a further embodiment of a wave power plant with a front and top view, partly cut,

Fig. 10 u. 11 the torque converter with front and side view, partly cut.

Fig. 1, 2 u. 3 shows the schematic structure of a wave power plant with three bucket roller wheels 11 . A housing body which is assembled from tongue body 14 , gau menkkörper 15 and cheek body 16 and is penetrated by three separate pharynx 17 . In the pharynx 17, the shovel roller wheels 11 are mounted transversely to the direction of the wave, With the housing body connected under half of the tongue body, a floating body 18 is installed in. The housing body rests in an articulated connection on a plurality of hydraulically adjustable support legs 19 . The support legs are mounted in carriages 20 , which are mounted on rails 21 so that they can move by motor. The running rails are laid as a closed circle on a base 22 which is anchored on the sea floor. In the jaw bodies, the torque converter 26 and the chain or belt transmission 34 are supported , which are connected by drive shafts in a force-locking manner to the bucket roller wheels 11 . The torque converters are still non-positively connected by drive shafts to the gears 35 for generators (or pumps) 36 . The gear 35 and the generators (or pumps) 36 are installed in the palate.

Fig. 1, 2, 3 u. 4 further shows the structure and the working principle of the wave power plant with three bucket roller wheels 11 . Here, the wave power station of the wave height, wave direction and wave position - resulting from high and low tide - hy draulically moved by the support legs 19 hy and rotated by the carriage 20 on the rails 21 motor and continuously adjusted Lich. The floating body 18 , which is located below half the water surface, has the task of stabilizing the wave power plant and relieving the weight of the wave power plant through its buoyancy.

The ocean waves are cut by the pointed edges of the tongue body 14 and the cheek body 16 , build up and run with little resistance over the tongue body into the pharynx 17 , with the aim of going through them. They meet the blades of the vane roller wheels 11 and set them in a rotary motion. The blades are shape, location u. designed numerically so that the wave energy is absorbed as calmly as possible. The blade roller wheels are arranged at a distance in the direction of the shaft and offset, and non-positively connected with chains or belt drives 34 . As a result, the swelling and decelerating shaft energy is shared between several bucket roller wheels and a more uniform torque is promoted. The power flow of the absorbed shaft energy he follows from the bucket roller wheels 11 via the gear 35 to the torque converter 26 and further to the gearbox for generators (or pumps) 35 , and generators (or pumps) 36 .

When using pumps, water is pumped into a reservoir or used to drive turbines. The water is sucked through openings 36 , which are located behind the vane roller wheels in the tongue body. The water drain reduces the water build-up on the paddle wheels and promotes the energy output of the water waves.

Fig. 5, 6 u. 7 shows the schematic structure and the mode of operation of a wave power plant with multiple screw conveyors 12 . The structure, the Arbeitswei se and the power flow of the wave power plant with conveyor screws corresponds to the wave power plant with shovel roller wheels, as Fig. 1, 2 u. 3rd

The wave energy is generated by the tooth flanks Screw conveyors added and in a rotary motion implementation implemented.

The floating body 18 is surrounded by a support ring body 23 , in which motor-driven toothed rollers 24 are mounted. The toothed rollers engage in a ring gear 25 , which is connected to the floating body 18 and the tongue body 14 . The support ring body is connected in an articulated manner on a plurality of hydraulically height-adjustable support legs 19 which are articulated on base bases 22 . By driving the sprockets, the wave power plant is adjusted to the direction of the waves and by adjusting the Tragbei ne the wave height and wave position.

Fig. 8 u. 9 shows the schematic structure and the mode of operation of a wave power plant with propeller screws 13 for a large water depth. Here, the wave power plant is installed in an immersion body 39 . The immersion body is designed with hollow chambers, which give it buoyancy. By ropes or chains 38 , which are anchored on the seabed, the immersion body is surely stabilized under the water surface. The structure, the working principle and the power flow corresponds to the wave power plant in Fig. 1, 2 u. 3. The wave energy is taken up by the propellers of the propeller screws and converted into a rotary motion. The immersion body can be used as a tank body in the case of production of hydrogen (electrolysis).

A support structure can be used for a medium water depth serve to accommodate the wave power plant.

Fig. 10 u. 11 show the schematic structure and the mode of operation of a torque converter 26 . This is composed of a main flywheel 27 , which is firmly connected to the drive shaft 29 and from two secondary flywheels 28 which are rotatably and axially displaceably mounted on the wheel hub of the main flywheel. In the wheel rims of the flywheels are several electro coils 30 u. 31 firmly used, which lie radially or axially opposite one another. The torque converter has the task of compensating for the non-uniform torque of the drive elements (resulting from the periodically increasing and decreasing wave energy), as well as the different energy quantities of the water waves (resulting from the height, length and running speed) in an energy-saving manner. This is solved by the fact that in a water wave with a small energy size only the main flywheel is in use, while the secondary flywheels stand still due to their storage and inertia. With increasing shaft size, one or both secondary flywheels are then coupled to the main flywheel. First, a growing magnetic field with different pole fields is induced in the electric coils 31 , which are located radially opposite one another. One or both secondary flywheels are slowly rotated by the attraction of the magnetic fields until a synchronous run with the main flywheel takes place. Subsequently, a magnetic field is induced in the electrical coils 30 , which are axially opposed, the forces of attraction magnetically coupling the secondary flywheels to the main flywheel. If the water waves become smaller again, one or both secondary flywheels are uncoupled from the main flywheel and slowly brought to a standstill. This is done by reversing the polarity of the electrical coils 30 , whose magnetic fields are now repelling each other and by the breakdown of the magnetic fields in the electrical coils 31 , and by the inertia of the secondary flywheels.

Fig. 10 u. 11 also shows the schematic construction of a torque converter, which is simultaneously formed as a generator rotor with a current winding 32 , and the generator stand 33 with a current winding. Due to the application and function of the torque converter as a generator rotor, the momentum energy is used directly, without additional drive from the generator gear and generator. This option has the advantage of saving energy, machines, investments and space requirements.

Reference numerals

11 = bucket roller wheels
12 = screw conveyors
13 = propeller screws
14 = tongue body
15 = palate
16 = jaw body
17 = pharynx
18 = float
19 = supporting legs
20 = carriage
21 = tracks
22 = basic base
23 = support ring body
24 = sprockets
25 = sprockets
26 = torque converter
27 = main flywheel
28 = secondary flywheels
29 = drive shaft
30 = axial electrical coils
31 = radial electrical coils
32 = current winding generator rotor
33 = generator stand with current winding
34 = belt - or chain transmission
35 = gearbox for generator or pumps
36 = generators or pumps
37 = openings
38 = ropes or chains
39 = immersion body

Claims (10)

1. wave power plant using the kinetic energy from water waves, in particular the energy from the horizontal wave movement, to drive generators or pumps,
characterized in that the wave power plant has a housing body which consists of tongue body ( 14 ), palate body ( 15 ) and cheek body ( 16 ) and is penetrated by open throat spaces ( 17 ) into which the water waves run
and with a plurality of drive elements which, depending on the design and mode of operation of the wave power plant, have bucket roller wheels ( 11 ), screw conveyors ( 12 ) or propeller screws ( 13 ) and which are rotatable and protected from the wind in the pharynx ( 17 ) with the task of extracting the energy from the wave motion record and set the drive elements in a rotary motion
and with a plurality of torque converters ( 26 ), which are mounted in the jaw bodies ( 16 ) or palate bodies ( 15 ), are positively connected to the drive elements ( 11 , 12 or 13 ) by chain or belt transmissions ( 34 ), with the task absorb the rising and falling wave energy and compensate for the uneven torque
and with a floating body ( 18 ), which is arranged below the tongue body ( 14 ) in the water, has a buoyancy, with the task of stabilizing the wave power plant, as to relieve its weight
and with a plurality of hydraulic support legs ( 19 ) which are connected to the housing body and are seated in carriages ( 20 ) which move by motor on rails ( 21 ) with a base ( 22 ), with the task of supporting the wave power plant and the direction of the wave, Wave height and the wave position (high tide, low tide) is essentially composed. 2. Wave power plant according to claim 1, characterized in that the wave power plant by a plurality of motor-driven sprockets ( 24 ), which are mounted in a support ring body ( 23 ), in conjunction with ring gears ( 25 ), with gene bodies ( 14 ) and floating bodies ( 18 ) are connected, is rotated. 3. wave power plant according to claim 1, characterized in that the wave power plant in a trench anchored on the seabed scaffold sits vertically and rotatably. 4. wave power plant according to claim 1, characterized in that the wave power plant in a diving body ( 39 ) is arranged vertically and rotationally Lich, which has a plurality of hollow chambers which give the diving body a buoyancy and with ropes or chains ( 38 ) on the seabed is anchored. 5. wave power plant according to claim 1, characterized in that the drive elements, bucket roller wheels ( 11 ), screw conveyors ( 12 ) or propeller screws ( 13 ) with a distance in the shaft running direction and laterally offset in the pharynx ( 17 ) and store by belt o. Chain gear ( 34 ) are non-positively connected to each other, with the task of distributing the swelling and declining shaft energy over several drive elements and to achieve the most uniform torque possible. 6. wave power plant according to claim 1, characterized in that the tongue body ( 14 ) have a plurality of openings ( 37 ) behind the Antriebsselemen th ( 11 , 12 and 13 ) into which water - with a pump function of the wave power plant - is sucked with the task of reducing the water build-up on the drive elements and promoting the energy output of the water waves on the drive elements. 7. wave power plant according to claim 1, characterized in that the torque converter ( 26 ) from a main flywheel ( 27 ) and two ne bungwheels ( 28 ) is assembled, in de NEN there are electric coils ( 30 ) and ( 31 ), depending on the structure , Dismantling and polarity reversal of the magnetic fields that couple or uncouple the flywheels ( 27 ) and ( 28 ) with the task of taking into account the energy sizes in light to heavy water waves by adjusting the flywheels. 8. wave power plant according to claim 1, characterized in that the torque converter ( 26 ) on the periphery of the main flywheel ( 27 ) is provided with a current winding ( 32 ) with the task of using the torque converter as a generator rotor at the same time. 9. wave power plant according to claim 1, characterized in that the drive elements ( 11 , 12 and 13 ) in the pharynx ( 17 ) are mounted above the shaft level and only the lower blades, worm teeth or propellers of the drive elements are inserted into the water waves. 10. wave power plant according to claim 1, characterized in that the tongue body ( 14 ), jaw body ( 16 ) and palate body ( 15 ) are keilför shaped and sharp-edged, with the task of cutting the water waves and favoring the run in the throat.