DE102014000866A1 - Controlled lift power plant for electric power generation - Google Patents

Abstract

The essence of the invention is that a system is developed, which produces a continuous buoyant body movement in liquid media (19) in that by means of a mechanical asymmetric endless guide (11) the volume content of flexible hollow bodies (1), (2), ( 5), which are attached to an endless traction means (6) and which transmits the driving force to these via deflection rollers (7) mounted in a frame, is enlarged in a wide buoyancy channel (12) and reduced in a narrow sink channel (13). The hollow body (1) are connected by a tube (14) in content with each other. Before starting the system, the flexible hollow body (1), (2), (5) via an inlet valve (21) in the tube (14) with gaseous media (16) filled with overpressure according to the height of the liquid (19) within the system , The in the hollow bodies (1) existing medium (16) high pressure is through the hose (14) in a basic version of radio-controlled location sensor-controlled electromagnetic multi-way valves (21) during circulation and thereby forced volume change of those in compression located in the expansion Hollow body (5) replaced by the pressure equalization. A deflection roller (7) is connected to a generator (18) for converting kinetic energy into electrical energy via a shaft (17) and a coupling (22). The plant according to the invention for generating electric power can be used anywhere where liquid media (19) for filling containers, basins or open waters are available.

Description

The invention relates to a system for generating electrical energy by means of controlled buoyancy force of variable volume hollow bodies and can be used anywhere where liquid media, eg. As water, for generating buoyancy on body of lower density than that of the surrounding liquid medium are present.

The aim of the invention is to produce electric energy environmentally friendly and resource-saving.

According to the invention the object is achieved in that a system is developed, which guarantees a continuous buoyancy force in one direction in liquid media in that a control of the buoyancy of hollow bodies, for. B. by asymmetric infinite mechanical guidance by the volume content of certain hollow bodies, which are gas-permeable connected by a hose, reduced to the downward movement in a narrow sink channel and increased for upward movement in a wide buoyancy channel, wherein the hollow body by endless traction means, for. As belt, chain, rope, belt are connected such that their movement is transmitted to mounted in a frame pulleys, which are connected via a shaft and a coupling with a generator for converting the kinetic energy into electrical energy.

The hollow body before starting the system via the inlet valve of the hose with gaseous medium, eg. As air, inflated pressure corresponding to the water level in the system from a pressure accumulator filled.

In a variant of the system, the gaseous medium present in the hollow body volume is diverted by the pressure via the hose and in particular via location-sensor-controlled electromagnetic multiway valves in the controlled volume change from the hollow bodies to be expanded to be expanded.

The plant according to the invention for the generation of electrical energy by buoyancy force is everywhere applicable, where liquid media for filling of containers, basins or reservoirs and flowing and dormant waters to the necessary water level in the system are available.

It is environmentally friendly and cheap to operate, as all control, operating and maintenance energy is diverted from the electricity produced.

It is independent of nuclear, fossil, solar and streaming wind and water energy.

The invention will be explained in more detail below with reference to exemplary embodiments.

1 Principle solution of a system with continuous motion generation by buoyancy of hollow bodies for electric power generation in section AA of 2

2 Cut BB from 1

3 Principle solution of a system with continuous motion generation by buoyancy of hollow bodies in balloon form for electric power generation in section AA of 4

4 Cut BB from 3

In 1 and 2 can be seen:
In the volume due to force variable hollow body 1 made of flexible, gastight, stretchable or foldable connecting materials 2 attached to two stiff plates 3 that have a joint 4 that with a leadership role 10 closes to the outside, are connected, are attached gas-tight and attached to an endless traction means 5 , z. As belt, tape or rope over another joint 6 are releasably connected, are in a liquid, eg. B. Water ( 19 ).

The traction device 5 is via pulleys 7 located in the upper and lower deflection center 8th in a rack 9 are stored, positively guided. On the hollow bodies 1 are also at the opposite side of the Zugmittelbefestigung side guide rollers 10 ball or slide bearing, in an endless, asymmetric around the pulleys 7 ongoing guideway 11 be guided positively. Between the traction means 5 and the guideway 11 is for the hollow body 1 a wide buoyancy channel 12 arranged, in the constricted spout, the hollow body 1 compressed and in a narrow sink channel 13 be introduced. The sink channel 13 leads to the lower pulley 7 expanded in the buoyancy channel 12 in which the hollow body 1 be pulled apart again. On the pulling means 5 is a gas-tight hose 14 arranged with all the hollow bodies 1 gas permeable is connected.

The hollow body 1 be before putting the hose over 14 through an inlet valve 27 with overpressure according to the water level in the system of a pressure accumulator 24 filled. During the circulation of the hollow body 1 becomes the gaseous medium 16 high pressure between the in-pressing and the widening hollow bodies 1 replaced by pressure equalization.

The guideway 11 is on a rack 9 attached, in which also the pulleys 7 are stored, or in conjunction with a fine-meshed surrounding grid 20 a protective function against contamination in an open water or other large fluid collections met.

A pulley 7 is with a wave 17 connected again with a liquid-proof generator 18 via a clutch 22 connected to the conversion of kinetic energy into electrical energy.

It is also in 3 and 4 a principle solution according to the similar procedure as in 1 and in 2 shown, in which the hollow body special balloons 5 are that without the plates 3 and the leadership roles 10 as well as a simplified guideway are designed and direct from the guiding geometry of the asymmetric infinite guidance 11 a volume reduction in the outlet of the wide buoyancy channel 12 in connection with the opening of the two assigned via radio location sensor-controlled multi-way valves 21 in the hose 14 and a simultaneous volume expansion in the inlet of the buoyancy channel 12 from the sink channel 13 experienced by the pressure equalization.

The location sensors 25 provide the signals for the opening of the respective channels of radio controlled electromagnetic multi-way valves 21 until closure by pressure control of the multiway valves 21 ,

LIST OF REFERENCE NUMBERS

1

hollow body

2

flexible materials, eg. B. gastight extensible and foldable joint surfaces between the rigid plates connected to the joints

3

plates

4

joints

5

balloons

6

Traction means, z. As belt, band, rope, chain

7

guide rollers

8th

Turning centers with bearings

9

Frame, also designed as a liquid container

10

guide rollers

11

endless asymmetrical roller track around the turning centers

12

Buoyancy channel for the hollow body in the state of large volume

13

Sinking channel for the hollow bodies in the state of small volume

14

gastight hose with hollow body connections and electromagnetic multi-way valves

15

Connecting web between guide rollers and plates

16

gaseous medium, e.g. For example, air

17

Wave to the generator

18

Generator for converting kinetic energy into electrical energy

19

liquid

20

guard

21

electromagnetic multi-way valves

22

clutch

23

Covering the liquid for containers

24

accumulator

25

Location sensors for the signaling at the inlet of the balloons, z. B. optical, magnetic, inductive and capacitive barrier sensors

26

Inlet valve (electromagnetic two-way valve)

27

Opening for access to the inlet valve

28

Connecting hose from the hollow body to the main hose

29

Parking brake with ventilation device

30

High pressure line with valve

Characteristic of the known state of the art

It is known that a variety of solutions to the use of buoyancy for energy production have been published, for. For example, more than a hundred relevant ones were found with the own IKOFAX search in class DE F03 B17 / 04 / icp.

As particularly obvious, the information in DE 302 1351 Device for generating energy by means of buoyancy bodies, DE 102 005 038 793 A1 Energy generator and EP 0930433 A1 Buoyancy engine as well DD 149 559 Hydropower plant for energy through buoyancy apply.

However, most of the proposed solutions have the disadvantage that the volume change should be made via piston movements that do not allow large volumes or set out any concrete solutions to other volume changes. So is in DE 10 2005 038 793 A1 only a "flap" for volume reduction indicated.

Also multi-shaped locks have been proposed, but have all the deficiencies in terms of functionality due to not calculated counter-forces of the liquid columns in the introduction of buoyancy in the buoyancy liquid or have significant water losses through the lock, which can not work without constant supply of appropriate amounts of water. In addition, all solutions that provide an exit from the liquid, with the same water volume decrease as that of the buoyancy body afflicted, which must be replaced in the exit height of the buoyant body, which corresponds to a potential of the Nachfüllwassers, which could also be used directly as a fall height.

The above shortcomings are to be eliminated by the proposed solution.

• DE 302 1351 Vorrichtung zur Energieerzeugung mittels Auftriebskörper
• DE 10 2005 038 793 A1 Energiegenerator
• EP 0930433 A1 Auftriebsmotor
• DD 149 559 Wasserkraftanlage zur Energieerzeugung durch Auftrieb

Patents considered for patentability:

• DE 302 1351 Device for generating energy by means of buoyancy bodies
• DE 10 2005 038 793 A1 power generator
• EP 0930433 A1 buoyancy engine
• DD 149 559 Hydropower plant for energy production through buoyancy

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 patent literature

• DE 3021351 [0022, 0026]
• DE 102005038793 A1 [0022, 0023, 0026]
• EP 0930433 A1 [0022, 0026]
• DD 149559 [0022, 0026]

Claims (10)

Controlled lifting power plant for electric power generation consisting of - variable in volume gas-tight hollow bodies, including balloons - an endless traction means - an endless asymmetric guide - guide and deflection rollers - bearings and joints - air hose with connection to the gas-tight hollow bodies and electromagnetic multi-way valves - location sensors for signals via radio to the electromagnetic multi-way valves - frame with a fine-meshed protective grid, also designed as a liquid container, characterized in that variable in volume by force variable gas-tight hollow body ( 1 ) and ( 2 ) on an endless traction means ( 5 ) over joints ( 4 ) and via a hose ( 14 ) are connected in a gas-permeable way and the guide rollers attached to them ( 10 ) in an endless asymmetrical guideway ( 11 ) in a rack ( 9 ) mounted pulleys ( 7 ) from a wide buoyancy channel ( 12 ) in a narrow sink channel ( 13 ) by a liquid ( 19 ). Controlled buoyancy power plant for generating electric power according to claim 1, characterized in that the hollow bodies ( 1 ) from two through joints ( 4 ) connected corrosion resistant plates ( 3 ) using flexible materials ( 2 ), z. B. gas-tight, stretchable and compressible or foldable connecting materials are gas-tight and connected to the corrosion-resistant plates ( 3 ) are made. Controlled buoyancy power plant for generating electric power according to claim 1, characterized in that the hollow bodies ( 1 ) of a gas-tight compressible, expandable and foldable balloon ( 5 ) consist. Controlled buoyancy power plant for electric power generation according to claim 1 and 3, characterized in that the variable in volume gas-tight hollow body ( 1 ) 2 ) and balloons ( 5 ) through a gastight tube ( 14 ) with radio-controlled location-sensor-controlled electromagnetic multi-way valves ( 21 ) are releasably connected. Controlled buoyancy power plant for electric power generation according to claim 1, 2, 3 and 4 characterized in that in the asymmetric infinite guideway ( 11 ) Location sensors ( 25 ) are arranged liquid-protected, by the frame ( 9 ) are liquid-tight exchangeable. Controlled buoyancy power plant for electric power generation according to claim 1, characterized in that the frame ( 9 ) is designed as a liquid container. Controlled buoyancy power plant for electric power generation according to claim 1, 2 and 3, characterized in that the frame ( 9 ) of a fine-meshed protective grid ( 20 ) is surrounded. Controlled buoyancy power plant for electric power generation according to claim 1, 2, 3, 4, 5, 6 and 7, characterized in that at least one of the deflection rollers ( 7 ) over a wave ( 17 ) with a liquid-powered generator ( 18 ) via a coupling ( 22 ) connected is. Controlled buoyancy power plant for electric power generation according to claim 1, 2, 3, 4 and 5 characterized in that the pressure accumulator ( 24 ) via a high pressure line with valve ( 30 ) a parking brake with ventilation device ( 29 ), which is the wave ( 17 ) with the deflection roller ( 7 ) is blocked, actuated. Controlled buoyancy power plant for electric power generation according to claim 1, 2, 3, 4 and 5 characterized in that the hollow body ( 1 ) 2 ) and ( 3 ) before putting the buoyancy plant into operation via the gas-permeable hose ( 14 ) and the electromagnetic two-way valve ( 26 ) as well as the opening ( 27 ) in the cover of the liquid for containers ( 23 ) for access to this valve with a gaseous medium, eg. As air, with pressure corresponding to the liquid level in the system from the accumulator ( 24 ) is filled.

Images