DE29517886U1 - Buoy with its own energy supply - Google Patents

Description

Patent Attorneys ···* '

Dipl.-Ing. Siegfried Schirmer, Bielefeld · Dipl.-Ing. Volker Specht, Berlin

Mtl ^Ht rtli AittiiMi'V

271/41-3 31.10.1995

German utility model application Applicant: Dipl.-Ing. Matthias Wrona-Charle

Schlehdornsteig 5 14129 Berlin

Dipl.-Ing. Bernt Geerken Nordstrasse 6

27404 Nartum

Buoy with its own energy supply

The invention relates to a buoy with its own energy supply through a fluid power machine, with an impeller rotating around a vertical axis by the mechanical energy of the flowing water with turbine blades protruding vertically into the water.

In the case of current-driven buoys, the electrical energy required for fairway lighting and for operation as a measuring station is generated by utilizing the mechanical energy of the flowing water, which is available almost constantly through rivers and tides, by driving a generator using an impeller set in rotation by the current.

For example, a buoy is known whose flow engine includes a screw wheel rotating around a horizontal axis, which is provided in a flow channel formed within the buoyancy body of the buoy. The use of this buoy requires a certain

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Minimum water depth in order to be able to use the largest possible screw wheel diameter to utilize the flow energy and also to avoid blockages in the flow channel.
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Furthermore, a flow-driven buoy has already been proposed, the flow engine of which is designed as an impeller turbine with an impeller (runner) that can rotate around a vertical axis and turbine blades (blades) arranged on its circumference that protrude vertically into the water. The turbine blades are essentially designed as narrow rectangular plates that can be pivoted centrally on the impeller around vertical axes. The angle of attack of the turbine blades is continuously changed by a control mechanism according to their position, which changes due to the rotation of the impeller, in order to achieve an optimal drive effect through the flow. Although this fluid power machine makes optimal use of the mechanical energy of the water and thus provides sufficient electrical energy, the control mechanism for adjusting the angle of attack of the pivoting turbine blades, which is equipped with a number of bearings and joints and is also complicated in construction and expensive to manufacture, is constantly exposed to the water and the dirt particles it contains, which can lead to malfunctions and a reduction in service life.

The invention is therefore based on the task of designing a buoy of the type mentioned at the beginning in such a way that its current engine can be easily manufactured with sufficient energy provision and also under the rough operating conditions in the flow of rivers and

Tides ensure trouble-free operation and a long service life.

According to the invention, the object is achieved in a buoy according to the preamble of claim 1 in such a way that the impeller is formed from blade plates that are rigidly mounted at an angle to one another between parallel, spaced-apart impeller plates, the blade plates being mounted at a distance from the center line of the impeller to form a central flow area for the water.

The basic idea of the invention therefore consists in a combination of resistance turbine and cross-flow turbine, where the flowing water first hits a blade plate and part of its mechanical energy is extracted from it, then as it flows through the free central space of the impeller it is directed to another blade plate and gives the impeller an additional movement impulse and finally exits the impeller on the other side.

The advantage of this solution lies in its uncomplicated, robust construction. The impeller is easy to manufacture, has at most one bearing exposed to the water and no other moving and therefore fault-prone components. This ensures trouble-free operation of the buoy with sufficient generation of electrical energy over a long period of time.

According to a further feature of the invention, at least two impeller halves arranged one above the other form a common impeller, in that between one of the impeller plates and a third impeller plate which is parallel to it at a distance, further blade plates as described above, but

to achieve a uniform torque, are mounted at an angle to the blade plates of the adjacent impeller half.

The impeller plates have a circular shape. Between two parallel impeller plates, three blade plates are arranged, offset by 120°, with the blade plates of one impeller half being offset by 60° from those of the other impeller half.

In a further embodiment of the invention, the blade plates consist of a straight section and an adjoining curved section that runs to the edge of the impeller plate, whereby the inner side of the blade plate exposed to the water pressure is the one with the concave surface of the curved section.

According to the invention, the inner sides of the blade plates are arranged at a distance from the center of the impeller plates, and the rear edge of the straight section is also spaced from the inner side of the following blade plate. This creates a flow area for the water in the central part of the impeller.

According to a further feature of the invention, the blade plates can also be arranged in such a way that their ends directed towards the interior of the impeller abut one another at the line connecting the centers of the impeller plates, so that no flow area is formed inside the impeller.

Further features and advantageous developments of the invention are set out in the subclaims.

An embodiment of the invention is explained in more detail using the drawing. They show:

Fig. 1 shows a longitudinal section through a current-driven buoy designed according to the invention with

Self-generated energy through a turbine;

Fig. 2 shows a section through a turbine impeller along the line AA in Fig. 1 with a central flow passage formed inside the impeller.

area for a part of the incoming water;

Fig. 3 another sectional view of the impeller,

but in a design without water flow area with centrally abutting

blade plate ends; and

Fig. 4 is a longitudinal section through the buoy of Fig. 1,

However, the radial bearing of the impeller above the water surface on the turbine shaft

he follows.

A turbine shaft 1 is guided within a standpipe 3 arranged in the barrel body of the buoy - mounted in a turbine shaft bearing 4 - and is connected to a generator 6 at its end remote from the water surface via a gear 5. At the opposite water-side end of the turbine shaft 1, an impeller 13 is attached, which is guided on an impeller bearing 9 fixed between the protective rods 7 of the buoy by holding rods 8. The impeller 13 consists of three circular impeller plates 10, 10' arranged parallel and spaced from one another, with three blade plates 11, 11' arranged offset by 120° from one another between each two opposing impeller plates 10, 10'.

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are rigidly attached. The blade plates 11 in the upper impeller half 13a are arranged offset by 60° from the blade plates 11' in the lower impeller half 13b.

From Fig. 2 and 3 it can be seen that the blade plates 11, 11' consist of a straight section 11a and a curved section 11b designed as a 90° circular arc. The curved section 11b gradually runs out at the peripheral edge of the impeller plates 10 or 10', while the straight section 11a runs at a lateral distance "a" from the center point "M" of the impeller plates 10, 10' or the center line of the impeller and the end of the adjacent blade plate 11, 11' in an anti-clockwise direction.

A blocking plate 12 is attached to the turbine shaft 1 at a short distance from the lower - water-side - opening of the standpipe 3, the diameter of which is larger than that of the standpipe 3. In this way, the small gap remaining between the underside of the barrel body 1 and the blocking plate 12 prevents water from reaching the turbine shaft bearing 4 in heavy waves.

The buoy is anchored in a river or in the sea. The impeller 13 lies completely below the water surface and is set in rotation by the river or tidal current, which is transmitted to the generator 6 via the turbine shaft and the gear 5. The rotation of the impeller 13 is generated independently of the direction in which the flow hits the impeller 13. The flowing water reaches the inside of a blade plate 11, 11' directly or via the back of the counterclockwise adjacent blade plate, i.e. the side of the blade plate with the concave curvature of the curved section 11b. This

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the impeller is set in a clockwise rotation. At the same time, with the blade arrangement according to Fig. 2, the water flows through the gap ("a") remaining between two blade plates against the inside of the third blade plate, in order to give the impeller a further movement impulse or in any case not to counteract the clockwise rotation and then exit from the inside of the impeller again. The arrangement of the blade plates 11, II ¹ offset by 60° compared to the other impeller half 13a or 13b contributes significantly to a uniform torque curve.

Fig. 3 shows a variant of the blade plate arrangement in which there is no flow area inside the impeller 13. In this case, the ends of the blade plates 11 abut one another at the center line of the impeller.

Fig. 4 finally shows an embodiment in which without the lower impeller bearing 9 located in the water and the support rods 8 for radial guidance of the impeller 13, a turbine shaft bearing 14 is provided arranged in the middle region of the turbine shaft 1.

This bearing is located above the water surface, so that the buoy and its energy-generating equipment are even less susceptible to failure.

List of reference symbols:

1 Turbine shaft 2 Barrel body 3 Standpipe 4 Turbine shaft bearings 5 transmission 6 generator 7 Protective rods 8th Grab bars 9 Wheel bearing 10, 10' Wheel plate 11, 11' Shovel plate 11a straight section of the blade plate lib curved section of the blade plate 12 Locking plate 13 Wheel 13a upper half of the wheel 13b lower wheel half 14 radial turbine shaft bearing

Claims (1)

t»· Protection claims : 1. Buoy with its own energy supply by a flow engine with an impeller rotating around a vertical axis by the mechanical energy of the flowing water with turbine blades projecting vertically into the water, characterized in that the impeller (13) is formed from blade plates (11) which are rigidly attached at an angle to one another between spaced-apart parallel impeller plates (10), the blade plates being arranged at a distance from the center line of the impeller (13) to form a central flow area for the water. 2. Buoy according to claim 1, characterized in that the impeller (13) consists of at least two impeller halves (13a, 13b) arranged one above the other with at least three impeller plates (10) and the blade plates (II ¹ ) of the lower impeller half (13b) are each arranged offset with respect to the blade plates (11) of the upper impeller half (13a). 3. Buoy according to claim 1 or 2, characterized in that the impeller plates (10, 10') have a circular shape and three blade plates (11 or 11') are provided, each offset by 120° to one another. 4. Buoy according to one of claims 1 to 3, characterized in that the blade plates (11, 11') consist of a straight section (Ha) and a curved section (lib) which gradually tapers off towards the edge of the impeller plates (10, 10'). 5. Buoy according to claim 4, characterized in that the curved portion (lib) is a 90° bend. .· &iacgr;&ogr; : &bgr;. Buoy according to one of claims 1 to 5, characterized in that the flow-loaded inner side of the blade plate (11) comprises the concave side of the curved section (lib) and the inner side of the straight section (lla) is arranged at a distance "a" from the center "M" of the impeller plate (10, 10') and the rear edge of the blade plate adjacent in an anti-clockwise direction, leaving a water flow area free. 7. Buoy according to one of claims 1 to 6, characterized in that the impeller (13) is surrounded by a protective rod (7) and is guided radially on the side opposite the turbine shaft (1) in an impeller bearing (9) which is attached to the protective rod (7) via holding rods (8), and is held axially in an upper turbine shaft bearing (4). 8. Buoy according to one of claims 1 to 7, characterized in that for the radial guidance of the impeller (13) a second turbine shaft bearing (14) is provided above the water surface - without the impeller bearing (9) and the support rods (8). 9. Buoy according to one of claims 1 to 8, characterized in that a locking plate (12) which spans the opening of the standpipe (3) is attached to the turbine shaft (1) at a short distance below the barrel body (2). 10. Buoy with its own energy supply by a flow engine with a rotating shaft driven by the energy of the flowing water around a vertical axis. Impeller with turbine blades projecting vertically into the water, characterized in that the impeller (13) consists of blade plates which are arranged at an angle to one another and rigidly mounted between spaced parallel impeller plates (10), which abut one another with their ends directed towards the interior of the impeller in the region of the center line of the impeller.