DE3938668A1 - Sea wave energy utilising equipment - has pipes of different shapes, moving with waves on floats, and aligning rudders - Google Patents

Abstract

The equipment delivers seawater above mean sea tide level via a tubular horizontal, water inlet section (2). A vertical Y-shaped pipe (8), a vertical top T-shaped one (10), an inclined connecting pipe of two tubes (14), and a vertical bottom T-shaped pipe (16) are included, all except the latter moving with the waves on floats (9). The water inlet opening (3) is aligned against the tide flow direction passively by rudders (5, 6). ADVANTAGE - No external energy required.

Description

genus

The invention relates to a method for using the potential Energy of the upper half waves of the sea and the gravitational waves simultaneously existing kinetic energy of the ocean current in energy generation.

The invention also has a hydromechanical device for lifting sea water above the medium level of the sea to the subject.

task

The invention has for its object a device to indicate which can serve without the supply of external energy Spend sea water in a level that is above the middle Level of swell is.  

solution

The method is based on the fact that the potential energy of the upper half-waves and those at the time of the upper Half-wave kinetic energy of the ocean current be used to bring sea water to a level which is above the average level of the sea.

The device for carrying out the method, referred to here as "wave rider", is shown schematically in FIGS. 1 and 2. It essentially consists of a number of tubes that can be rotated or pivoted relative to one another. It is mounted almost entirely under water and for this purpose is attached with its lower end to a stationary object ( 20 ) by means of a movable parallelogram mechanism in such a way that it stands vertically and is essentially movable in the vertical direction. Floats ( 9 ) at their upper end cause them to move with the ocean waves ( 1 ).

The wave rider has a horizontal tubular water inlet part ( 2 ) with a side inlet opening ( 3 ) for the sea water and a protective grille ( 4 ) just below the float ( 9 ). The water inlet part ( 2 ) is inserted into a Y-tube ( 8 ) and freely rotatable about its horizontal axis AA. The Y-tube ( 8 ) sits on the swivel joint ( 13 ) on the upper T-tube ( 10 ) and is in turn freely rotatable about the vertical axis FF. A directional rudder ( 6 ) and a rotary rudder ( 5 ) are located on the water inlet part ( 2 ). With the help of the directional rudder ( 6 ) the water inlet part ( 2 ) is rotated together with the Y-tube ( 8 ) by the ocean current around the axis FF so that the axis AA comes to lie perpendicular to this flow. With the help of the rotary rudder ( 5 ), the water inlet part ( 2 ) is rotated by the flow about the axis AA in such a way that the inlet opening ( 3 ) opposes the flow. This happens in particular because the center of gravity of the water inlet part ( 2 ) is outside the axis AA on the side opposite the inlet opening ( 3 ). The sea water can therefore flow in freely through the inlet opening ( 3 ).

The arm ( 11 ) rigidly attached in the lower extension of the upper T-tube ( 10 ) lies between the horizontal pivot axes BB and DD and forms one side of the movable parallelogram mechanism. The other three parallelogram sides are formed by the connecting line ( 14 ), the strut between the boom joint ( 12 ) and the horizontal pivot axis E and by the vertically oriented stationary object ( 20 ) between the horizontal pivot axes CC and EE. The wave rider is not rotatable about the vertical axis of symmetry GG of the lower T-tube ( 16 ).

A check valve ( 18 ) ensures that the seawater in the wave rider can only flow in the direction from the inlet opening ( 3 ) to the outlet opening ( 19 ).

The path of the water leads from the inlet opening ( 3 ) into the water inlet part ( 2 ), through the through openings ( 7 ) into the Y-tube ( 8 ), past the swivel joint ( 13 ) into the upper T-tube ( 10 ), through the upper passage openings ( 15 ) into the two arms of the connecting line ( 14 ), through the lower passage openings ( 17 ) into the lower T-pipe ( 16 ), and finally through the check valve ( 18 ) to the outlet opening ( 19 ).

A riser pipe can be connected to the outlet opening ( 19 ), in which the sea water detected by the wave rider is passed into a reservoir, the content of which lies above the average level of the sea state.

The seawater caught by the wave rider can in particular also a level still up to about 10 m higher if the sea water level in the storage tank through a corresponding vacuum is raised. This can be used to capture what is caught by the rider To bring sea water out of the area of the sea.  

advantages

The wave rider uses the potential energy of the upper one Half waves also the kinetic energy of the ocean current, to seawater above the medium level of swell in one Spend memory. From the storage tank, the sea water can be medium level of swell or in the appropriate ones Time intervals are also led down to the wave valleys and do work.

The sea water can reach a level up to about 10 m higher be spent if the sea water level in the storage tank a corresponding vacuum is raised. That can serve the seawater from the area of the Bring out sea waves.

The rider can be used to advantage in the Patent application from the same day (internal file number P 2638), namely in a method and an apparatus for the extraction of fresh water from relatively warm sea water.  

Structure of the device

Figs. 1 and 2 show a possible embodiment of the invention.

Fig. 1 shows a schematic representation of the wave rider in front view,

Fig. 2 shows a schematic representation of a part of the wave rider, in particular its attachment, in side view.

For orientation, the sea surface ( 1 ) and a fixed object ( 20 ) for attaching the surfers are entered in the illustration.

The wave rider contains a horizontal tubular water inlet part ( 2 ) with an inlet opening ( 3 ), on which there is a protective grille ( 4 ), a rotary rudder ( 5 ), a directional rudder ( 6 ) and a vertical Y-tube ( 8 ) with floats ( 9 ). The water inlet part ( 2 ) is inserted into the Y-tube ( 8 ). It has openings ( 7 ) on both sides to the Y-tube ( 8 ).

The wave rider also contains a vertical upper T-pipe ( 10 ) with bracket ( 11 ) and bracket joint ( 12 ), a swivel joint ( 13 ) between Y-pipe ( 8 ) and upper T-pipe ( 10 ) and an inclined connecting line ( 14 ) consisting of two arms. The connecting line ( 14 ) penetrates the upper T-tube ( 10 ) in its upper part. The connecting line ( 14 ) has upper through openings ( 15 ) towards the upper T-tube ( 10 ) in the upper middle.

The wave rider also contains a vertically standing, fixedly attached lower T-tube ( 16 ) with a check valve ( 18 ) and an outlet opening ( 19 ). The connecting line ( 14 ) penetrates the lower T-tube ( 16 ) in its lower part. The connecting line ( 14 ) also has lower passage openings ( 17 ) towards the lower T-tube ( 16 ) in the lower center.

The water inlet part ( 2 ) is freely rotatable about the horizontal axis AA. The Y-tube ( 8 ) can be freely rotated about the vertical axis FF. The upper T-tube ( 10 ) and the connecting line ( 14 ) can be pivoted about their common horizontal axis BB. The connecting line ( 14 ) is also pivotable about the horizontal axis CC, which it has in common with the fixed bottom T-tube ( 16 ). The boom joint ( 12 ) can be pivoted about the horizontal axis DD. There is a strut between the boom joint ( 12 ) and the horizontal pivot axis E attached to the stationary object ( 20 ). The lower T-tube ( 16 ) and thus the entire device cannot be rotated about the vertical axis GG.

The boom ( 11 ), the connecting line ( 14 ), the fixed object ( 20 ) between the pivot axes C and E and the strut between the boom joint ( 12 ) and the pivot axis E together form a movable parallelogram mechanism.

Function of the device

The lower part of the device is attached to the stationary object ( 20 ) and can move essentially in the vertical direction via the parallelogram mechanism with the horizontal axes BB, CC, DD and EE. Floats ( 9 ) ensure that the movable part of the device moves with the vertical movement of the ocean waves.

Due to the swivel joint ( 13 ) with the vertical axis FF, the Y-tube ( 8 ) together with the water inlet part ( 2 ) can be rotated as desired. The directional rudder ( 6 ) attached to the water inlet part ( 2 ) causes the Y tube ( 8 ) and the water inlet part ( 2 ) to be rotated about the vertical axis FF by the ocean current in such a way that the horizontal axis AA is aligned perpendicular to this flow .

The water inlet part ( 2 ) can be rotated as desired about the horizontal axis AA. The mounted on the water inlet portion (2) of rotation rudder (5) causes the water inlet portion (2) is rotated by sea currents to the horizontal axis AA that its openings (3) to align opposite to the direction of the flow. This happens in particular because the center of gravity of the water inlet part ( 2 ) is located outside the axis AA in a position opposite the inlet opening ( 3 ).

Under the conditions described, the sea water flows at sea or when flowing through the inlet opening ( 3 ) into the water inlet part ( 2 ), from there into the Y-pipe ( 8 ), from there into the upper T-pipe ( 10 ), thence into the two arms of the connecting line ( 14 ), from there into the lower T-tube ( 16 ) and further to the outlet opening ( 19 ). The check valve ( 18 ) means that the sea water can only flow in the direction just described.

Through the outlet opening ( 19 ) the sea water can be brought via a riser into a storage tank, where it receives a potential which is above the potential of the average sea state. From the reservoir, the sea water can be conducted down to the medium level of the sea or, at the appropriate time intervals, down to the wave valleys and do work.

The sea water can also reach a level that is about 10 m higher be spent if the sea water level in the storage tank a corresponding vacuum is raised. Additional work can be done not done in this way, but this is Procedure for the flash evaporation of sea water of great Use.

Claims (10)

1. A device for bringing sea water over the medium level of the sea state, characterized in that the device has a horizontal, tubular water inlet part ( 2 ), a vertical Y-tube ( 8 ), a vertical upper T-tube ( 10 ), an oblique has lying connecting pipe ( 14 ) consisting of two pipes and a vertical lower T-pipe ( 16 ) and, with the exception of the fixed lower T-pipe ( 16 ), it is moved with the sea by means of the floats ( 9 ) and its water inlet opening ( 3 ) with the help of a directional rudder ( 6 ) and a rotary rudder ( 5 ) is passively aligned against the current ocean current. 2. Device according to claim 1, characterized in that the water inlet part ( 2 ) is freely rotatable about its horizontal axis AA. 3. Apparatus according to claim 2, characterized in that the center of gravity of the water inlet part ( 2 ) lies outside the axis AA on the inlet opening ( 3 ) opposite side. 4. The device according to claim 1, characterized in that the Y-tube ( 8 ) is freely rotatable about its vertical axis FF. 5. The device according to claim 1, characterized in that the upper Y-tube ( 10 ) and the connecting line ( 14 ) are pivotable about their common horizontal axis BB. 6. The device according to claim 1, characterized in that the connecting line ( 14 ) about its horizontal axis CC, which it has in common with the fixed lower T-tube ( 16 ), is pivotable. 7. The device according to claim 1, characterized in that the vertically oriented stationary object ( 20 ) between the horizontal pivot axes C and E, the connecting line ( 14 ), the boom ( 11 ) and the strut between the boom joint ( 12 ) and the horizontal Pivot axis E form a parallelogram mechanism which can be pivoted in the vertical direction, such that the arm ( 11 ) is always vertical. 8. The device according to claim 1, characterized by a check valve ( 18 ) such that the absorbed sea water can only flow in the direction from the inlet opening ( 3 ) to the outlet opening ( 19 ). 9. Device according to one of claims 1 to 8, characterized in that the path of the water from the inlet opening ( 3 ) in the water inlet part ( 2 ), through the through openings ( 7 ) in the Y-tube ( 8 ), on the swivel joint ( 13 ) over into the upper T-pipe ( 10 ), through the upper passage openings ( 15 ) into the two arms of the connecting line ( 14 ), through the lower passage openings ( 17 ) into the lower T-pipe ( 16 ) and finally through the check valve ( 18 ) leads to the outlet opening ( 19 ). 10. Procedure for moving seawater over the medium level of swell, thereby characterized that potential energy the upper ocean half-waves and those at the time of the upper Ocean half waves each have kinetic energy the ocean current is used.