NL1001163C2 - Windmill for generation of electrical power - Google Patents

Abstract

The hub of the rotor is a conical case mounted on a conical core assembly. The core assembly is mounted on the top of a braced mast. The vanes of the rotor are up to 50 metres long. The inner ends of the vanes are mounted on a frame consisting of rods, rings spokes and rollers. Pneumatic or hydraulic actuators are used to vary the pitch of the blades. Inside the conical hub are a work surface for maintenance personnel and a fixed crane for moving components, during installation or repair. Speed monitors and other sensing instruments can also be mounted inside the cone.

Description

Short designation: Windmill.

The invention relates to a device for the conversion of wind flow energy into mechanical and possibly electrical energy, comprising a basic construction connected to a land or water surface and a rotor rotatably mounted on the basic construction for a number each connected to a supporting arm which can pivot about its axis. vanes, the main direction of which makes an angle with the axis direction of the supporting arm, and wherein, viewed in the wind direction, a tapering wind guide is arranged upstream of the vanes.

Such a device is known from patent application PCT / NL93 / 00090.

Unlike the most common types of windmills for the conversion of wind energy into mechanical or electrical energy, where a base structure or mast carries a generator housing and the blades, when viewed in the wind direction, are arranged upstream of the generator housing is located here on the downstream side of a house in which or under which the 20 power generators are housed. The wind conductor serves to conduct the incoming wind at the largest possible radius relative to the axis of rotation to the blades, because at that larger radius a considerably higher efficiency for the conversion of wind flow energy into mechanical energy can be achieved. The arrangement of the wind deflector and vanes relative to the basic construction results in the device being able to direct itself to a favorable position in the wind to a great extent, without special control.

The object of the invention is to propose various improvements of the earlier type, in particular, but not exclusively, aimed at increasing the dimensions, and of course with a view to increasing the converted power.

First of all, the invention is characterized for this purpose in that 10 0 1 1 63.

- 2 - the wind deflector is arranged rotatably about a substantially vertical axis with respect to the basic construction, and the rotor is rotatably mounted about a substantially horizontal axis with respect to the wind deflector.

5 Especially with large dimensions - to determine the thoughts, the wind guide size in the wind direction can be up to 50 meters or longer, while the blade length is in the same order of magnitude - a safer product can be constructed when the wind guide is rotatable about a head A vertical axis is arranged in relation to the basic construction or mast, while a rotor rotatable separately about a substantially horizontal axis is then used in relation to the wind deflector. Thus, the safety of the user during construction, inspection, maintenance, service and repair increases because an important part of the aforementioned work can take place in the wind deflector.

In order to overcome the associated drawback that a large wind conductor also experiences a correspondingly greater wind load, with the inevitable consequences for the whole construction but especially for the construction of the mast, the device according to the invention is preferably designed such that the wind conductor comprises a jacket which is partly fixed, and partly consists of elements which are pivotable or can optionally be slid under each other or under fixed parts of the jacket, in order to reduce the surface of the wind conductor and thereby the total wind load thereon at high wind strengths.

This idea is incidentally also applicable to the prior art embodiment in which the wind guide is part of the rotor.

In a further preferred embodiment, the wind deflector of the device according to the invention has a fixed frame provided with means, such as a work floor, for performing work in the interior of the wind deflector, and storing tools therein and / or materials.

Precisely because of the large dimensions that can be 10 0 1 1 63.

- 3 - applied when using a substantially fixed wind deflector, it becomes quite possible to carry out maintenance, repair and inspection in the interior of the wind deflector. This is of course much easier and more comfortable than performing such work from the outside of the device, at the base of the basic construction or elsewhere.

In another preferred embodiment, lifting means are incorporated in the wind guide, which are designed such that they can operate outside the interior space of the wind guide.

For simplified blade maintenance, or disassembly or replacement, the wind deflector is dimensioned so that its interior space can accommodate at least one of the blades at least partially, with means provided for carrying each included blade . In combination with the aforementioned hoisting means and the possibility of folding out the wicks in line with the wind guide, a relatively simple manipulation of wicks is possible without the use of external hoisting means, in particular if the hoisting means have a carrier of an adjustable length include.

With these measures it is also possible to bring current generators and such parts within the operating range, in particular if the hoisting means can be active through the internal space of the basic construction.

Preferably, one or more anemometers, i.e. meters for wind speed, wind direction and / or wind density, are arranged on a support, which support, viewed in the wind direction, extends substantially upstream to a distance from the wind guide. Such an arrangement of the meter (s) allows early anticipation of changes in wind speed, wind direction and / or wind density for the corresponding adjustment of the angles. The risk of overloading the device or parts thereof is greatly reduced with this measure, while optimum use can also be made of the wind energy present.

tanning 1 e- 3.

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In order to increase the efficiency of the device, a flap or brush is provided on the end of the wind deflector facing the blades along at least almost the entire circumference thereof, which flap extends the jacket surface of the wind deflector substantially to the side facing the wind deflector. of the blades in its most widely spread position. Thus, a smooth transition between the wind guide and the blades takes place, and undesired turbulences at the end of the wind guide facing the blades are avoided as much as possible.

In a preferred embodiment, a separate generator for the energy supply for the blade adjustment is attached to the rotor, which generator with a running wheel touches a running surface of the fixed frame of the wind guide 15. This ensures that no energy for the blade adjustment has to be transferred from a stationary system (wind deflector) to a rotating system (rotor and blades); the energy is generated as well as used in the rotating system.

In the event that the energy supply for the blade adjustment is cut off or fails, an automatic reset device on the rotor is provided for autonomously placing the blades in a safe position. Such an automatic reset device can for instance consist of a tensioned spring, which may also include a gas spring. The safe position of the blades is that in which the blades extend substantially parallel to each other on the downstream side of the wind deflector.

Preferably, the wind guide is substantially conical in shape, the tip of the cone being turned away from the blades. The tip of the cone may also be rounded. Other tapering shapes, such as a spherical segment, an ellipsoidal segment or a paraboloid segment, can also be used as a wind guide.

The invention will be explained below with reference to the appended drawing.

Fig. 1a of the drawing schematically shows a vertical section through a conical wind deflector rotatable about a vertical axis, placed on a basic construction, with only a partial representation of the blades; Fig. 1b schematically shows, on an enlarged scale, a detail of the vertical section according to Fig. 1a through a part of the wind guide adjoining the blades; Fig. 2 shows the single wind deflector jacket; Fig. 3 shows a schematic cross-section through the whole wind guide, in a plane perpendicular to the wind guide; and Fig. 4 shows, in a partial vertical section through the wind deflector, on the same scale as Fig. 1b, further preferred measures to be applied.

FIG. 1a schematically shows a basic construction or mast 1, here conceived as a lattice construction, which carries a wind deflector indicated in its entirety by 2, which will hereinafter be referred to as "cone". This cone 2 is built up from a cone frame 3 with a cone jacket 4 mounted thereon.

The cone frame may be composed of a set of beams such as 5 (cf. the schematic cross-section of Fig. 3) which run along descriptive lines of the cone shape and which are arranged in suitable places, in particular around the opening of the cone on the blades facing side, may be provided with sleepers (not shown). Furthermore, the frame can be dm.v. an upright 6 supporting a work floor 7 in the interior space of the cone 2.

In the cone 2 there is also a rotor gear 11 30 which mainly consists of three rings 12a, 12b and 12c which are mutually connected by means of spokes 13, Fig. 1a showing only a part of the total number of spokes. The rotor gear 11 thus constructed is by means of Rotatably alloyed rollers 14 supported in a manner not shown in detail and rotatable about a substantially horizontal axis. The rotor gear is coupled via a suitable transmission in a manner not shown in more detail to one or more power generators, for example in a similar manner as that described in patent application PCT / NL93 / 00090.

In the embodiment shown, the rotor gear 11 carries four operating elements 15 with which arms 16 carrying blades 17 of the rotor can rotate about the axes of the operating elements. This rotational movement gives the blades 17 a combined movement which allows them to collapse into a position substantially opposite to the cone shaft, as described in the said patent application 10 PCT / NL93 / 00090.

In Fig. 1b, a wick 17 with an operating element 15 is shown in more detail, but without further detail of the attachment of the operating element 15 to the rotor gear 11. The operating element 15 comprises a shaft 15a, which can be rotated in two places encamped in armies 15b. The shaft 15a is by a flange connection 15c connected to the arm 16 carrying the wick 17. Rotation of the shaft 15a results in a displacement of the wick 17 in the area indicated by a double arrow between the position indicated by 20 solid lines and the position indicated by broken lines of the wick 17. The position of the wick 17 is adjusted by driving a lever arm 15d connected to the end of the shaft 17a away from the wick 17 by means of a cylinder piston unit 15e coupled thereto. The cylinder piston unit 15e may include a spring which causes the piston rod to assume the safe position shown in solid lines in Fig. 1b when the pressure in the cylinder piston unit 15e drops when the power supply for the wick adjustment is interrupted.

In order to reduce the wind load on the conical surface, it is proposed according to the invention to make parts of the conical surface foldable or slidable, as is schematically shown in fig. 2 and 3. D.m.v. hinges such as 20 that run along descriptive lines of the cone, pieces 4a of the cone jacket 4 are pivoted. They can therefore be inserted inwardly, approximately in radial planes, as indicated by 4 '. In 10 01 1 63.

- 7 - this position, of course, has not reduced the wind-braking surface of the wind deflector completely to zero, but has greatly reduced it.

There are also conceivable solutions other than the pivotability 5 to realize this idea. For example, parts can be pushed one behind the other. Sections of the cone face near the top can then perform a small inward displacement and slide behind a next section, together behind a third section and so on. The 10 cone casing parts are thus superimposed in the manner of scales. This idea is also feasible in the circumferential direction of the conical plane, i.e. in the direction perpendicular to the descriptive lines.

According to Figs. 1a and 3, a telescopic lifting beam 21 is placed in the cone 2. The lifting beam can be extended beyond the plane of the rotor ring 12b in order to then be able to carry out work on the blades 17, in particular to bring them inwards into the wind guide so that maintenance work can be carried out on them. The blades 17 can also be lowered or removed outside the cone after disassembly. be picked up from there. Naturally, a different placement and design of the lifting beam 21 is also possible than on the work floor 7 as outlined in Fig. 1a. In particular, another solution is that the space within the base structure 1 is used for lifting and lowering materials, including the blades. The basic construction is preferably built up for this purpose from at least five lattice girders 9 connected by guy wires 8, in which case the upright 6 and the work floor 7 are provided with a lockable passage.

Referring again to Fig. 1a, it can be seen that the tip of the cone 2 is provided with a protruding carrying rod 22 for one or more wind measuring instruments 23. While it is usual in windmills known to place the wind speed meter behind the rotor - in particular on the house of the generator in cases where the rotor is in front of the house with generator - one now gets to the 10 0 1 1 63.

- windmill in which the generators are housed within the cone through which the wind is guided to a larger diameter, the possibility of already changing the position of the blades if the wind measurements at the location of the measuring instruments give cause to do so. To determine the thoughts: if the cone size according to the axis direction would be 50 meters and the length of the carrier 22 another 10 meters, then at a wind speed of 48 km per hour, 5 sec. control time before the wind whose properties are measured at 10 23 reaches the blades 17. By more accurately adapting the position of the blades to the wind speed at any time, the efficiency is increased and the device as a whole is loaded more evenly than in the prior art.

It can subsequently be seen in Fig. 1 that on the open side of the cone along the entire circumference thereof a flap 24 is arranged which is substantially parallel to the conical surface. This can consist of a rubber-like material, or optionally of a bundle of hair, i.e. a brush. The flap 24 extends just to the location of the blades 17 in its widest position. The flap 24 serves to bridge the gap between the end of the actual cone and the blades, due to the presence of the carrying rod 16 for each of those blades, in such a way that no energy is consumed in that annular zone, but on the contrary all air flowing off the conical surface is effectively guided to the blades.

Fig. 4 shows another aspect of the invention. A current generator 25 is arranged fixedly with respect to the rotor frame 11. This is rotated by means of a roller 26 which is continuously in contact with a part 27 of the fixed frame of the cone 2. The electric power developed by the generator 25 can be used to adjust the blades 17. If desired, any wick 17 have its own generator 25. The electrical connections between the generator 25 and the operating element 15 which ensures the rotation of the wing arm 16 are not shown, nor are the electronic control system for the wing gear.

Finally, it is also indicated in Fig. 1a that the cone can comprise a deck 30 with a closable access opening to the interior of the cone 2. Such a provision is particularly useful for, for example, using e.g. depositing a helicopter of persons and materials on a windmill located on a water surface for carrying out maintenance, inspection, etc. For similar reasons, the cone can also be provided with entrances on the sides thereof.

1001 1 bl

Claims (12)

1. Device for the conversion of wind flow energy into mechanical and possibly electrical energy, comprising a basic construction connected to a land or water surface and a rotor rotatably mounted on the basic construction, for a number each of which is connected with a supporting arm pivotable about its axis, the main direction of which makes an angle with the axial direction of the support arm, and in which, viewed in the wind direction, a tapering wind guide is arranged upstream of the blades, characterized in that the wind guide (2) is rotatable with respect to the basic construction (1) around an a substantially vertical axis is disposed, and the rotor (11) is rotatably mounted about a substantially horizontal axis relative to the wind deflector (2). 2. Device according to claim 1, characterized in that the wind guide (2) comprises a jacket which is partly fixed and partly consists of elements (4 * S) which are pivotable or optionally stepped under each other or under fixed parts can be slipped off the jacket. Device according to claim 1 or 2, characterized in that 2. the wind deflector (2) has a fixed frame (3) provided with means, such as a work floor (7), for carrying out work in the interior of the wind deflector (2), and storing tools and materials therein Device according to any one of claims 1 to 3, characterized in that the wind guide (2) is dimensioned such that its internal space can at least partially accommodate at least one of the blades, wherein means are provided for carrying each included wick. 3 0 Device according to claim 3 or 4, characterized in that the wind guide (2) includes lifting means (21) which are designed such that they can operate outside the interior space of the wind guide. 6. Device as claimed in claim 5, characterized in that the hoisting means comprise a carrier with an adjustable length. Device according to any one of claims 3-6, characterized in that the hoisting means can act through the internal space of the basic construction (1). Device according to one of the preceding claims, characterized in that one or more anemometers (23) are arranged on a support (22), which support, viewed in the wind direction, extends substantially upstream to a distance from the wind guide. (2). 9. Device as claimed in any of the foregoing claims, characterized in that a flap or brush is arranged at least at the entire circumference thereof at the end of the wind guide which faces the blades and which extends the jacket surface of the wind guide substantially up to the 15 extends the side of the blades facing the wind guide in its most spread position. Device according to any one of the preceding claims, characterized in that a separate generator (25) for the energy supply for the blade adjustment is attached to the rotor, which generator with a running wheel (26) has a running surface (27) of touches the fixed frame (3) of the wind deflector (2). 11. Device as claimed in any of the foregoing claims, characterized in that the rotor (11) is provided with an automatic reset device for bringing the blades in a safe position in the event of failure of the energy supply for the blade adjustment. 12. Device as claimed in any of the foregoing claims, characterized in that the wind guide is substantially conical. 10 01165.