DE102010012288A1 - Method for self controlling wave power plant for obtaining electricity and drinking water from sea, involves obtaining required energy from waves in autonomously operating combined system for obtaining electricity from sea - Google Patents

Abstract

The method involves obtaining the required energy from the waves in an autonomously operating, combined system for obtaining electricity and drinking water from the sea. The lever arms are mounted on a support-structure anchored on the sea bed, such that the lever arms with the float gauges fixed at the longer lever arm follows the up and down movements of the waves by their drive. The smaller lever arm transfers these movements onto a piston pump.

Description

Subject of the Invention - Brief Description

With the different water level between wave trough and wave crown electrical energy and / or drinking water is obtained.

On a scaffold anchored on the seabed near the coast, a pump system is operated in a height-adjustable manner via Hebelwerk. It automatically adjusts itself to the tides and waves so that the optimum energy yield always succeeds.

For the duration of destructive wave heights, it pulls itself into a protective depth of water. For maintenance tasks, it is extended over water.

In the open sea, the system is connected to an anchored structure.

Floats, on correspondingly mounted lever arms, actuate by their buoyancy piston pumps.

The condensed water is led into a pressure or high tank.

From there, the water is directed to a turbine that drives a generator.

Systems are designed several times and connected in series.

For drinking water production by reverse osmosis the existing water pressure is brought to the required operating pressure with the generated electric power.

State of the art

Science and technology endeavor to harness the enormous energy potential of ocean currents and waves.

There are systems in the testing that want to use less the waves as energy sources, more the accompanying currents.

Examples: A system is installed in the Thames Estuary, as well as off the Scottish and Canadian coasts.

On the Atlantic coast of France, a tidal power plant works, which makes use of the enormous tidal range there. You exit flow previously dammed water is used. This principle is being tested or in operation at various other locations, especially on the Atlantic coast.

A power plant has been in operation in the Azores for 10 years, generating electricity from wave power with a technical system that has been installed firmly on the coastline, with little success so far.

All these systems suffer particularly from the disadvantage that they can be used only limited and in a few places worldwide. The technique of converting wave power directly into energy has often had to cope with setbacks and is generally still in development.

The extraction of drinking water from the sea is already practiced on a large scale. However, cost-generating and cost-effective energy quantities are used. Only where, on the one hand, there is no alternative and, on the other hand, energy is available cheaply can seawater desalination be justified at an acceptable cost. However, environmentally harmful fossil fuels are used throughout.

Drinking water from the sea is obtained mainly by evaporation or by reverse osmosis. The effort is still high.

Researchers at the University of California in Las Angeles have now developed a membrane with nanotunnels, which brings advantages over the previous systems for reverse osmosis.

The goal

The waves, especially on the oceans and near the coast, represent a remarkable energy potential. Waves are stored solar energy.

This renewable, ultimately inexhaustible, solar energy means an absolutely clean, never-ending, environmentally friendly source of energy.

The generation of electricity and the simultaneous production of drinking water from seawater is possible without the aid of other sources of energy.

My goal is to use wave energy for this purpose, with a mixture of simple and safe technology and high-tech control.

Each plant should work automatically and with known, proven technologies.

According to scientific studies, a very important part of the energy needed worldwide could be obtained from the power of the waves.

The task:

Drinking water production from the sea is becoming increasingly important worldwide. In many regions of the world, people, and nature in general, suffer from the lack of (clean) drinking water.

With my method can be generated at the same time, with the energy gained from the waves, electricity and drinking water from the sea to be won. Both can be done in a network system. This requires no energy from other sources.

The procedure:

A working on meaningfully arranged lever constructions pump system generates, driven by the wave movements, pressurized water. This generates electricity via turbines. With it, the seawater is brought to the required pressure for the function of reverse osmosis.

Only a fraction of the pressurized seawater is used for the production of drinking water. The remaining, constantly flowing water is returned to the cycle for power generation. Thus, a part of the energy used for pressure generation can be recovered.

There remains electrical energy z. B. can be used for the further transport of water to the end user.

The technique of the pump system can be used advantageously near the coast, but also on the open sea.

The technology

1. support structures:

Pylons or generally stable carrier structures or carrier scaffolds are firmly anchored on the seabed. 2 and 3 ,

Instead of anchoring support structures on the seabed, they can also be firmly connected to anchored on the open sea, carrier platforms.

2. Lever arms and cylinders:

On the support structures according to item 1, lever arms are technically used on a joint in such a way that they absorb floats on the longer arm. The shorter arm acts on cylinders with pistons. 3 . 4 and 5 ,

When entering a wave trough with its slight overweight, the longer lever arm retracts the piston in the pump to its starting position, the upper reversal point. 2 . 4 and 5 ,

The orientation of the lever or the lever is directed with its floats against the known main direction of the waves or, in the mirror image arrangement, facing away from this. 4 . 5 and 8th ,

Floats can act on several interconnected lever systems. 6 ,

3. The piston pump:

The piston pump is attached to the support structure vertically below the shorter lever arm. The piston presses the water which has flowed into the cylinder via a pressure line into a pressure vessel or into a high-level reservoir. 1 and 2 ,

4. The floats:

Swimmers on the longer lever arm follow the ups and downs of the wave movements.

The up and down movements, caused by the different water level between wave crown and wave trough, transfer the energy gained by the buoyancy to the other, shorter end of the lever. This acts on the piston pump. 3 . 4 and 5 ,

The floats are latched over a connection between lever arms, hung and fixed in such a way that they can follow the currents minimized resistance.

As a result, most of the mechanics are underwater and thus less exposed to the forces of wave motion. 2 ,

Hanging swimmers respond more flexibly to the forces of waves and wind. With their control fins, they can more easily fit themselves in the prevailing flow, in the most resistant position. 3 to 8th ,

Not only for a better adaptation to flow conditions, but also for a more efficient energy yield, it is advantageous to flexibly and rotatably attach several floats on each lever arm. 6 to 8th ,

5. Double arrangement of pumping systems:

Lever arms with the pumping systems are arranged in mirror image. They are in the support structure on one side against the shaft and on the opposite side mirror image arranged. Each wave is thus used twice. 3 to 8th ,

6. Mode of action:

During the downward movement of the longer lever parts, water is sucked in the cylinder of the piston pump. As the floats rise onto a shaft, the piston of the pump is depressed at the shorter end of the lever. The water that has flowed into the cylinder is compressed and forced into a pipe system. Valves control the inflow and outflow of the water. 1 and 2 ,

7. Pressure vessel or reservoir:

The water pushed into the pipe is directed into a pressure vessel. 1 and 2 ,

The pressure vessel works with known technology. It regulates the set, desired or required pressure by means of a gas cushion and keeps it constant within set tolerances. 2 ,

Instead of in a pressure vessel, the water can also be directed into high collection or storage tanks.

8. Turbine Generator:

A drainpipe from the pressure vessel, or reservoir, directs the water to a turbine coupled to a generator. 1 and 2 ,

The turbine with the generator is driven by the incoming water according to traditional technology.

9. Increasing the water pressure:

The electricity generated by the generator drives electrically operated pumps that bring the water to the pressure required for reverse osmosis. 1 ,

10. Drinking water production:

The now high pressure water flows around the membranes for reverse osmosis. The flow is adjusted so that contamination of the membranes can be largely prevented.

11. The reflux of pressurized water:

Even after the freshwater extraction by reverse osmosis, the remaining seawater is still under high pressure. It is returned to the water for the operation of the generator and is available again with its remaining energy for power generation. Check valves regulate the flow of water. See point 8.

12. The structure above and below water:

Firmly anchored pylons carry the technology of lever systems and pumps. 3 . 4 and 5 ,

They are movably connected to the pylons and height adjustable along these with gears via racks. Sensors detect data and send it to computers. Geared motors keep lever systems with the floats always adjusted in the calculated, for the energy yield most favorable position level. 5 ,

Each installed system includes storage media, such as storage media. B. Batteries that provide, if necessary, regardless of external energy sources, the power for the lifting and lowering movements.

Thus, the entire system always works in the changing tidal tides with the optimum efficiency, with the best possible use of wave energy.

The pylons stick out of the water. With the exception of the swimmers, the entire technical system works underwater. 2 ,

Rolling wave crests thus do not damage the working structure. Likewise, possible damage to the material, which could be caused by the constant change of seawater and air, is reduced.

13. The self-protection mechanism:

In order to prevent damage to the technology in heavy seas, it is meanwhile driven underwater into a safe area.

A mechanism can vent the floats.

Sensors calculate time and duration of underwater operation.

14. Maintenance:

The entire technical system can be driven over the water for maintenance with the geared motors.

15. Multiple system combined:

The technical systems can be combined in such a way to multiple systems that they feed a common pressure vessel with seawater. They are then put together in positions that are based on the local conditions and the most efficient energy yield.

A system can consist of four lever arms, which are combined into two lever pairs. Each pair of levers is coupled to one or more piston pumps. 6 to 8th ,

It is possible that 12 or more individual systems thus bring water into the same pressure vessel or reservoir. The more interconnected systems, technically limited in number, the more uniform the pressure water flow into the pressure vessel and the safer the supply of turbines for power generation.

Combined arrangements result in savings in investment and maintenance.

The efficiency is increased.

By the successive or side by side switching of systems, there are also savings in the construction of support structures.

16. Pumped storage plants

With suitable geographical conditions, the plants can also be operated as storage facilities. That is, the seawater is pumped into a higher reservoir. The return to the turbines for power generation, takes place controlled and as needed, for. B. for the geared motors to start up or shut down.

17. Cleaning the membranes for reverse osmosis

With fast flowing water, the contamination of membranes can be avoided quite effectively.

To further counter contamination of the membranes for reverse osmosis, a known physical process can be used.

If the flow of pressurized water is suddenly stopped, a sudden overpressure occurs in the piping system, combined with a short-term violent vibration. As a result, settlements are released at the membranes and taken from the re-released water flow.

18. Consideration of power fluctuations

• 1. Bei geringer Ausbeute an elektrischem Strom wird dieser bevorzugt zur Erzeugung von Trinkwasser genutzt. Die verbleibende Energie reicht möglicherweise nicht für den Weitertransport. In diesem Falle wird auf Vorrat produziert, das Süßwasser wird gespeichert.
• 2. Steht wieder ein Überschuss aus elektrischer Energie zur Verfügung, wird das gespeicherte Süßwasser bis zum Verbraucher weitertransportiert.

The swell is not always consistent, the energy production changes. Variations in the energy yield are compensated. There are possibilities:

• 1. With low yield of electric current, this is preferably used for the production of drinking water. The remaining energy may not be enough for onward transportation. In this case it is produced in reserve, the fresh water is stored.
• 2. Once a surplus of electrical energy is available, the stored fresh water is transported on to the consumer.

19. Annex:

A technical innovation

Article in DER SPIEGEL Nr. 46/2006 <Drinking water from nanotunnels> or similar suitable fine filter.

Researchers at the University of California in Los Angeles have used nanotechnology to develop a process that can be used to inexpensively produce drinking water from salt or dirty water. Usually desalination plants use the principle of reverse osmosis. At high pressure, contaminated water is forced through a semi-permeable membrane. As with a filter, only the pure water molecules on the other side arrive. The disadvantage is that the membranes rapidly lose efficiency because bacteria and other substances adhere to them. Environmental engineer Eric Hoek and his team have now created a better membrane that is criss-crossed by tiny nanotunnels. The advantage: Bacteria, salts and other dirt are literally rejected by the new material. A water treatment plant according to this technique, Hoek insists, uses only half as much energy as usual.

LIST OF REFERENCE NUMBERS

1

Technisches System Wellenkraftwerk

2

Druckbehälter

3

Turbine

4

Generator

5

Pumpe

6

Wasseraufbereitung Umkehrosmose

7

Süßwasser

8

Pumpe für Trinkwasser zum Verbraucher

9

Elektrische Stromführung

10

Rückfluss ins Meer

11

Sammelleitung für Druckwasser

12

Rückleitung von Restwasser

13

Zuleitung zum Verdichter vor Umkehrosmose

Fig. 2

1

Gerüst oder Pylonen im Meeresboden oder Fundament

2

Unterseeboden oder Fundament

3

Meerwasser

4

Schwimmer

5

Hebelarm langer Teil

6

Kolbenpumpe

7

Luftpolster im Druckbehälter

8

Druckbehälter

9

Druckwasserleitung zum Druckbehälter

10

Turbine

11

Generator

12

Wipplager für Hebelarme

13

Druckwasserleitung zur Turbine

14

Wellenkamm

Fig. 3, 4

1

Steuerflossen

2

Laufrichtung der Wellen

3

Höhenverstellung des Systems

4

Zahnstangen für Höhen/Tiefenverstellung und Nivellierung

5

Sockel oder Fundament auf dem Meeresgrund zum Verankern der Pumpensysteme

Fig. 6, 7 und 8

1

Strömungsrichtung – Wellenrichtung

2

Wipplager für Hebelarme

3

Kolbenpumpe

21

Gerüst oder Pylonen

22

Hebel, Hebelarm

Fig. 1

1

Technical System Wave Power Plant

2

pressure vessel

3

turbine

4

generator

5

pump

6

Water treatment reverse osmosis

7

Freshwater

8th

Pump for drinking water to the consumer

9

Electric power supply

10

Reflux into the sea

11

Manifold for pressurized water

12

Return of residual water

13

Supply line to the compressor before reverse osmosis

Fig. 2

1

Scaffolding or pylons in the seabed or foundation

2

Subsoil or foundation

3

seawater

4

swimmer

5

Lever arm long part

6

piston pump

7

Air cushion in the pressure vessel

8th

pressure vessel

9

Pressure water line to the pressure vessel

10

turbine

11

generator

12

Wipplager for lever arms

13

Pressure water line to the turbine

14

wave crest

Fig. 3, 4

1

control fin

2

Direction of the waves

3

Height adjustment of the system

4

Racks for height / depth adjustment and leveling

5

Base or foundation on the seabed for anchoring the pump systems

FIGS. 6, 7 and 8

1

Flow direction - shaft direction

2

Wipplager for lever arms

3

piston pump

21

Scaffolding or pylons

22

Lever, lever arm

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• DER SPIEGEL Nr. 46/2006 <Drinking water from nanotunnels> [0075]

Claims (10)

The process for a self-governing wave power plant for the production of electricity and drinking water from the sea is characterized by the fact that in an autonomously working, combined system for the production of electricity and drinking water from the sea, the required energy is extracted from the waves. The method for a self-propelled wave power plant for power and drinking water from the sea is characterized according to claim 1, that on a, anchored to the seabed support structure, lever arms are mounted so that they are attached to the longer lever arm floats, by their buoyancy , the ups and downs of the wave movements can follow, the shorter lever arm transmits these movements to a piston pump. The method for a self-propelled wave power plant for power and drinking water from the sea is characterized according to claim 2, characterized in that the support structure for the lever system consists of firmly anchored, projecting beyond the water surface pylons on which racks are guided and on the one hand, when the sea is too rough, with gear motors all the technology, sensor-controlled, pulled underwater for their protection and on the other hand can be extended for maintenance work on water. The process for a self-propelled wave power plant for electricity and drinking water from the sea is characterized according to claim 2, that coming from the pump, pressurized seawater, is first pressed into a high or pressure vessel and from there to the turbines for power generation to be led. The process for a self-propelled wave power plant for the production of electricity and drinking water from the sea is characterized according to claim 4, characterized in that the power generated is primarily used to operate pumps, the seawater in a second, leading from the pressure vessel line to a for the reverse osmosis brings appropriate pressure so that it can be used to produce drinking water. The method for a self-propelled wave power plant for the production of electricity and drinking water from the sea is characterized according to claim 4 and 5, characterized in that the seawater residue, after flowing through the reverse osmosis device, is returned so that it supplies energy together with the water from the pressure vessel a second time passed through the turbine. The method for a self-propelled wave power plant for the production of electricity and drinking water from the sea is characterized according to claim 3, characterized in that the entire system operates under normal conditions under the water surface and that sensors, the working position of the system with respect to the sea surface and the tides, so control and control that always the best possible energy yield is guaranteed. The process for a self-propelled wave power plant for the production of electricity and drinking water from the sea is characterized according to claim 2, that at the longer lever arm one or more, equipped with stabilizing control fins float are flexibly mounted so that they always align themselves automatically in the most aerodynamic position , The process for a self-propelled wave power plant for the production of electricity and drinking water from the sea is characterized according to claim 2, characterized in that the complete lever systems are arranged with floats and pumps mirror images of the support structure, d. H. both against and with the wave movements are aligned and effective. The process for a self-propelled wave power plant for electricity and drinking water from the sea is characterized according to claim 2 and 3, characterized in that several complete systems - leverages, floats and pumps - are interconnected so that they come via a pressure line, the coming out of the pump water Press in the same pressure or high tank.

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