WO1994019605A1

WO1994019605A1 - Wind turbine

Info

Publication number: WO1994019605A1
Application number: PCT/EP1994/000568
Authority: WO
Inventors: Egon Gelhard
Original assignee: Egon Gelhard
Priority date: 1993-02-26
Filing date: 1994-02-26
Publication date: 1994-09-01

Abstract

The wind turbine proposed comprises a mast (2) on which is mounted a propeller (3) which drives a generator (8). The power at the propeller shaft is transmitted to the generator (8) hydraulically. The propeller preferably drives a hydraulic pump (5) which is connected by hydraulic lines (6) to a hydraulic motor (7) driving the generator. The hydraulic transmission make it possible to locate the very heavy generator (8) in a machinery house on the ground. This reduces the load on the mast and thus makes it possible to design the mast and its foundation to be lighter and cheaper. In a power-generation facility made up of several wind turbines (1, 1', 1''), the individual hydraulic pumps (5, 5', 5'') associated with the individual propellers (3, 3', 3'') can be connected up to the same hydraulic motor (7, 7', 7''). This makes it possible to make optimum use of the wind energy, particularly at low wind speeds.

Description

Wind turbine

The invention relates to a wind turbine. The known wind turbines consist of a tower which carries a rotor with several rotor blades. A generator, which generates the electrical energy, is coupled to the rotor via a transmission gear. Power plants with several wind turbines are also referred to as wind farms.

In order to be able to use the higher wind speed at higher altitudes, the tower should have a large construction height. However, the construction of a high tower is associated with considerable technical effort, especially since the heavy generator of the known wind turbines arranged on the tower head requires a very stable structure. Plants with an output of up to around 200 KW are built in a tubular steel structure. Larger systems use a reinforced concrete tower as the supporting structure. A further disadvantage of the known wind turbines is that a minimum wind speed is required to turn the rotor.

The object of the invention is to create a wind power plant whose tower or its foundation can be constructed in a simple manner with relatively little effort.

The object is achieved according to the invention with the features of claims 1,, 6 and. 9th

In the wind power plant according to the invention, the power on the rotor shaft is transferred hydraulically to the generator. The rotor advantageously drives a hydraulic pump which is connected via pressure medium lines to a hydraulic motor driving the generator.

The hydraulic power transmission makes it possible to place the very heavy generator on the ground in a machine house. As a result, the main load of the tower is reduced, so that an easier and less expensive design of the tower and the foundation is possible. In this way, towers with a large overall height can be erected with relatively little effort and the performance of the system increased.

In a power plant that has a plurality of wind power plants, the hydraulic pumps assigned to the individual rotors can be switched to a common hydraulic motor. As a result, wind energy can be optimally used even at low wind speeds. Even if the wind speed falls below a certain limit, the hydraulic pumps Pen of the individual rotors together drive a generator with the optimal speed or the optimal torque.

In order to facilitate the erection of the tower, the tower can be tilted from the horizontal position into the vertical position, preferably with a hydraulic drive. A crane for erecting the tower mounted on the floor is therefore not necessary.

The tower is a tube construction made of tubes that run obliquely upwards with horizontal struts. The essentially vertical tubes of the tower consist of individual tube segments that can be assembled telescopically and are delimited by stops. The horizontal struts of the tubular construction form an angular frame, at the corner points of which tubular connecting pieces are provided which enclose the tubular segments and hold the vertical tubes together firmly. The tower can be assembled on site in the manner of a modular system from the tube segments and the angular frame. The individual parts can be assembled into towers of different heights. They can also be transported to the installation site with smaller vehicles. Heavy transporters for the transport of larger assembly units are therefore not necessary.

It is particularly advantageous that the foundation of the tower can also be built in a simple manner. To erect the foundation, it is only necessary to drill holes in the ground into which a suitable filler material is injected. The foundation strands which extend into the earth and branch in all directions, which run from central foundation head out, ensure an optimal connection of the tower to the ground.

The wind forces acting on the tower are advantageously intercepted with lateral arms which are attached to the foundation heads. The cantilevers are connected at their free ends to bases, from which, in turn, foundation strands formed in the manner of a root extend into the ground. The number and length of the lateral support arms can be adapted to the local conditions.

Several exemplary embodiments of the invention are explained in more detail below with reference to the drawings. Show it:

1 is a hydraulic circuit diagram of a power plant consisting of several wind turbines,

2 the tower of a wind turbine in a side view,

3 is a partial view of the tower tilted out of the vertical position,

4 shows a section through the tower of FIG. 2 along the line IV-IV,

Fig. 5 shows the detail A of Fig. 2 in an enlarged and partially sectioned representation, and

Fig. 6 shows part of the foundation on which the tower is built. 1 shows the hydraulic circuit diagram of a power plant consisting of several wind power plants 1, 1 ', 1 ". The wind power plants 1, 1', 1" each have a tower 2, 2 ', 2 ", which has a rotor 3, 3', 3 "with two rotor blades 4, 4 ', 4" and a hydraulic pump 5, 5', 5 "driven by the rotor.

The hydraulic pump of each wind turbine is connected via pressure medium lines 6, 6 ', 6 "to a hydraulic motor 7, 7', 7" which drives a generator 8, 8 ', 8 ". The hydraulic motors assigned to the individual wind turbines are located together with the generators in a machine house next to the towers.

1, the pressure medium line connecting the pressure connection of the hydraulic pump 5 to the pressure connection of the hydraulic motor 7 is designated by the reference number 9, while the line connecting the return connection of the hydraulic motor 7 to the suction-side pressure medium connection of the hydraulic pump 5 is also shown the reference 10 is designated. Shut-off valves 11, 11 ', 11 "are provided in the pressure medium lines 6, 6', 6" between the hydraulic pumps and hydraulic motors. When the valve is open, the hydraulic pump and the hydraulic motor of each wind turbine form a closed pressure medium circuit. When the valve is closed, the pressure medium lines are shut off.

The pressure connections and the suction-side connections of the hydraulic pumps 5, 5 ', 5 "of the individual wind turbines are connected to one another via two connecting pressure medium lines 12, connection valves 13, 13 being located in the connecting branches between the hydraulic pumps of two neighboring wind turbines ', 13 ", with which the hydraulic pumps of the interconnect individual wind turbines or have them separated from each other. With the connecting valves, the hydraulic pumps 5, 5 ', 5 "can be switched from two or more wind turbines to a common generator 8, 8', 8". This is advantageous at low wind speeds or in the event of a generator failure.

In the valve position shown in FIG. 1, the hydraulic pumps 5, 5 'of the wind turbines 1, 1' are switched to the hydraulic motor designated by the reference numeral 7 ', while the hydraulic motor 7 is switched off. The hydraulic pump 5 "of the wind power plant 1" forms a separate pressure medium circuit with the hydraulic motor 7 ", since the connection valve 13 'or 13" is blocked. By opening the cut-in valve 13 'and blocking the cut-off valve 11 ", the hydraulic pump of the third wind turbine 1" can also drive the generator 8'. Furthermore, expansion tanks 14, 14 ', 14 "are also provided, which are connected to the pressure medium line 12.

Fig. 2 shows the tower 2 of a wind turbine in a side view. The tower 2 is a tubular steel construction comprising three tubes 16 which converge at an upward angle and which are connected with horizontal struts 15 to form an angled frame, the tubes 16 forming the corner points and the struts 15 forming the legs of an isosceles triangle.

The tower 2 is fastened to a foot part 17 so as to be pivotable about a horizontal axis 18. The foot part 17 of the tower 2 consists of three supports 19 which are connected with horizontal struts 20 to form an angularly fixed frame which stands on a foundation which is under 6 will be described in more detail.

Two of the three tubes 16 of the tower 2 are connected via articulated connections 21 to the upper ends of the tube pieces 19 of the foot part 17, while the piston rod 22 of a piston-cylinder arrangement 23 is articulated to the lower end of the third tube. The cylinder 24 of the piston-cylinder arrangement 23 is connected in an articulated manner to the third pipe section 19 of the foot part 17. By retracting the piston of the piston-cylinder arrangement, the tower can be erected from its horizontal mounting position and then screwed to the foot part 17. FIG. 3 shows a partial view of the tower 2 when the piston of the piston-cylinder arrangement 23 is retracted.

In order to facilitate the transport of the tower 2 and to be able to erect towers of different heights, the tubes 16 of the tower consist of telescopic tube segments 25 which can be assembled on site. The horizontal struts 15 are screwed and / or welded at their ends to the inner half-shells 26 of pipe clamps 27, which firmly enclose the pipes 25. The horizontal struts 15 together with the pipe clamps 27 form an angular frame in the form of an isosceles triangle (FIG. 4).

5 shows the pipe segments 25 '25 "which are connected to one another together with a horizontal strut 15 in a partially sectioned representation. Since the inner diameter of the lower pipe segment 25' is slightly larger than the outer diameter of the upper pipe segment 25", the pipe segments 25 can be push into each other, the upper tube segment 25 "also a stop 28 on the upper edge 29 of the lower pipe segment 25 'is supported. The pipe segments 25 are thus secured against axial displacement. The pipe segments 25 are secured against twisting by fitting bolts 30. The fitting bolts 30 are firmly seated in mutually aligned bores 31 of the two pipe segment ends. A second stop 32 is provided at the upper end of the lower pipe segment 25 '. Between the two stops 28, 32 lies the inner half-shell 26 of the pipe clamp 27 of the angular bracing frame 35. The upper pipe segment 25 'is thus supported with its stop 28 on the upper edge 29 of the lower pipe segment 25' and on the upper one Edge of the pipe clamp 27, while the lower edge of the pipe clamp 27 rests on the stop 32 on the outer wall of the lower pipe segment 25 '. The lower pipe segment 25 'is provided with one or more longitudinal slots 33. By screwing the half-shells 26 of the pipe clamp 27, the pipe segment ends are clamped together.

Fig. 6 shows a part of the foundation on which the tower 2 is built. The pipe sections 19 of the foot part 17 are each fastened to a plate-shaped foundation head. 5 shows one of the three foundation heads 34 of the foundation. Steel-reinforced foundation strands 36, which are designed in the manner of a root, extend from the foundation head 34 into the base 39 in all directions. Furthermore, the lateral head 37 made of steel arranged in a star-shaped or beam-like manner extends from the foundation head 34. The free ends of the cantilevers 37, of which only one cantilever is shown in FIG. 6, rest on a base 38, from which, in turn, steel-reinforced foundation strands 36 formed in the manner of a root originate. The foundation can be built in a simple manner using the following method. First, 39 holes 40 are drilled into the subsurface, which are graded in themselves. In these holes 40 is mixed and prepared z. B. polyester concrete is pressed in under high pressure, so that the flowable concrete mass penetrates into all the gaps and cavities of the subsurface adjacent to the bores and causes a branching. The foundation heads 34 and the bases 38 of the brackets 37, which connect the upper ends of the foundation strands 36 to one another, are then cast on the substrate.

Claims

Expectations

1. Wind turbine with a tower (2) which carries a rotor (3) which drives a generator (8) for generating electrical energy, characterized in that the generator (8) is arranged on the ground, and that the transmission of power to the rotor shaft is carried out hydraulically on the generator (8).

2. Wind power plant according to claim 1, characterized gekenn¬ characterized in that the rotor (3) drives a hydraulic pump (5) which is connected via pressure medium lines (6) with a generator (8) driving hydraulic motor (7).

3. Power plant with several wind turbines according to claim 2, characterized in that the individual rotors (3, 3 ', 3 ") associated with hydraulic pumps (5, 5', 5)" on a common hydraulic motor (8, 8 ', 8 ") are switchable.

4. Wind power plant consisting of a base part (17) with a foundation, a tower (2) errich¬ on the base part (17), which carries a rotor (3), characterized in that the tower (2) around a horizon¬ tale axis (18) is pivotally attached to the foot part (17).

5. Wind power plant according to claim 4, characterized gekenn¬ characterized in that a hydraulic drive (23) for erecting the tower (2) is provided.

6. Wind power plant with a tower (2) which carries a rotor (3), the tower (2) having a pipe con Structure of the tubes (16) converging obliquely upwards with horizontal struts

(15), characterized in that the tubes

(16) consist of individual, telescopically assembled pipe segments (25) which are delimited by stops (28, 32) and that the horizontal struts (15) form an angular frame (35), at the corner points of which pipe-shaped Mige connecting pieces (27) are provided, which embrace the tube segments (25) placed one against the other.

7. Wind power plant according to claim 6, characterized gekenn¬ characterized in that the tube segments (25) are slotted at their ends and that the tubular connecting pieces are pipe clips (27).

8. Wind power plant according to claim 6 or 7, characterized in that the tubular connec tion pieces (27) between the stops (28,32).

9. Wind power plant with a er¬ erated on a foundation tower (2) which carries a rotor (3), characterized in that the foundation has at least one foundation head (34), from which in the underground (39) after Extend the foundation strands (36) formed like a root.

10. Wind power plant according to claim 9, characterized gekenn¬ characterized in that each foundation head (34) has at least one horizontal boom (37) which supports the tower (2) against laterally acting wind forces.

11. Wind power plant according to claim 10, characterized gekenn¬ characterized in that a base (38) is provided at the free ends of the boom (37), from which extend into the ground (39) in the manner of a root formed foundation strands (36) .