DE9218214U1 - Wind converter, especially for areas with little wind - Google Patents

Description

Applicant:

Med. univ. Dr. Hans Mölzer Tummelplatz 6/3/8 A-8010 Graz
Austria

WIND CONVERTERS, ESPECIALLY FOR LOW WIND AREAS

The invention relates to a wind converter, in particular for low-wind areas, according to the preamble of claim 1.

Such a wind converter is already disclosed in DE-OS 29 49 057. In this wind converter, the rotor is provided with up to 50 vanes or rotor blades, which are pivotably mounted between a rotor axis and the rotor casing. The generator housing is arranged in the area of the hub of the rotor and is designed as a double-cone-shaped guide body on both sides of the rotor, tapering outwards, with the vertical axis of rotation around which the wind converter can pivot, located in front of the generator housing in the direction of the wind flow.

ISARPATENT» ¹

The disadvantage of this previously known wind converter is its
complex structure with numerous moving parts and, above all, a low energy yield. In addition, the high number of wings or rotor blades causes air congestion problems and the associated braking effect, which significantly impairs the efficiency of the wind converter.

Three-blade wind converters are also known and are already being used on the North Sea coast, for example. The blades are adjustable in their angle of attack and have a cross-sectional profile that tapers radially outwards. As a result, there are smaller inflow areas in the radial outer areas, which exert a comparatively greater leverage on the rotor axis than the inner areas of the blades, so that the efficiency of three-blade models also needs to be improved. In addition, there is separation of the air flow and the formation of vortices in the area of the radial blade ends, which is unfavorable for energy yield for fluidic reasons.

The invention is based on the object of further developing a wind converter of the type mentioned at the beginning with regard to a more favorable energy yield with a simple structural design.

According to the invention, this object is achieved by the features characterized in claim 1. Preferred features that advantageously further develop the invention can be found in the subordinate patent claims.

The invention therefore advantageously creates a wind converter that is particularly suitable for low-wind areas, in which the incoming air is effectively directed to the periphery of the rotor, where the leverage of the rotor blades on the rotor axis is greater than in the middle area of the rotor. This makes it possible to achieve this in a favorable manner in low-wind areas, i.e. in windy areas.

speeds of around 20 to 25 km/h (approx. 3 Beaufort) five times more energy from the moving air mass can be converted than with the three-bladed turbines currently known. The wind converter according to the invention is also more cost-effective than the wind converter known from the above-mentioned DE-OS 29 49 057, since the wind energy is not directed to the periphery of the rotor, but rather to the center of the rotor, where the energy yield is the lowest.

Preferably, the length of the paraboloid-shaped wind deflector, which extends to approximately 3/7 of the rotor diameter towards the rotor, is approximately 0.7 times the rotor diameter D. Due to this configuration, self-alignment of the wind converter into the optimal flow position is advantageously achieved during operation, in which the wind deflector is oriented opposite to the wind flow direction.

The maximum diameter of the aerodynamically expanding paraboloidal wind deflector is advantageously chosen in such a way that the center field area of the rotor in the rear end of the wind deflector, which is about 3/7 of the rotor diameter, is covered. This effectively optimizes wind utilization by increasing the use of the wind flow in the outer area of the rotor. The ring-shaped rotor casing contributes favorably to the flow guidance and concentration and prevents the radial migration of flow components and the formation of undesirable flow vortices.

The wind converter according to the invention is also characterized by a particularly simple structural design, which leads to advantages in production and maintenance. In particular, the fixed installation of 16 rotor blades between the rotor disk and casing reduces the number of moving parts in the area of the rotor to just one moving part, which consists of the rotor axis and rotor. The rotor blades are preferably designed for

Wind flow direction inclined by approximately 45°

To further improve the flow conditions in the inflow area, according to a preferred embodiment of the invention, the wind deflector has wind deflector elements on its surface which extend in a straight line from the region of the crest to the end of the wind deflector, the number of which is preferably 16 and which are preferably formed as longitudinal grooves in the wind deflector.

It is also advantageous in terms of aerodynamics if, according to a preferred embodiment of the invention, the annular rotor casing extends against the wind flow direction from the end of the rotor blades attached to it to beyond the end of the paraboloid-shaped wind deflector, since this achieves a certain "bundling" of the incoming wind into the interior of the rotor casing.

The width of the annular rotor shroud is preferably about 1/5 to 1/4 of the rotor diameter, and the rotor blades preferably have an aircraft wing cross-sectional profile that is constant in the radial direction, wherein the width of each rotor blade is about 1/6 to 1/5 of the rotor diameter.

According to a preferred embodiment of the invention, the rotor has 16 rotor blades which are attached to a central rotor disk, the diameter of which is approximately 3/7 of the rotor diameter.

A comparison of the wind converter according to the invention with a three-blade "Aeroman" type aircraft with the same rotor diameter and the same wind speed resulted in an energy yield that was about six times higher.

The invention is explained in more detail below using an embodiment in the accompanying drawings. They show:

Fig. 1 shows a schematic longitudinal section through an embodiment of a wind converter according to the invention; and

Fig. 2 is a front view of the wind converter according to Fig. 1 seen in the wind flow direction.

The figures show a schematic representation of a wind converter 10 intended especially for low-wind areas. The wind converter 10 consists of a generator housing 11, a rotor 12 and a bearing device 13 housed in the generator housing 11, via which the generator housing 11 can be pivoted about a vertical axis of rotation 14, which coincides with the longitudinal axis of symmetry of a support mast 15.

The generator housing 11 contains a mounting frame 16 in which a generator 18, a gear 19 and a bearing 20 are mounted on a support 17. The support 17 is supported on the bearing device 13 designed as a rotating platform. A further bearing 21 is provided on the mounting frame 16 in the middle of the end of the generator housing 11. The generator housing 11 is surrounded by a paraboloid-shaped wind deflector 22 which, like a jacket, encloses the generator housing 11, forming a dome 23 and an outlet opening 24 for the support mast 15, whereby the rear end of the wind deflector 22 is also closed around the bearing 21. The paraboloid-shaped wind deflector 22 is modeled on the head of a projectile and ensures a low-turbulence deflection of the wind that hits the wind converter 10 from the wind flow direction indicated by arrow A.

As indicated in Figure 2, the wind deflector 22 has wind deflector elements 24 on its surface, which extend in a straight line from the area of the dome 23 to the rear end of the wind deflector 22. A total of 16 wind deflector elements 24 are provided, which are evenly distributed over the surface of the wind deflector 22 and are formed in a streamlined manner as molded-in longitudinal

grooves are formed.

The rotor 12 has a central rotor shaft 25 perpendicular to the axis of rotation 14, which is mounted horizontally within the generator housing 11 in the bearings 20 and 21. The rotor shaft 25 is attached to a rotor disk 26 and extends to the gear 19. A coupling shaft 27 is located between the gear 19 and the generator 18.

The rotor disk 26 has a diameter d that is approximately 3/7 of the diameter D of the rotor. A total of 16 rotor blades 28 are attached centrally to the rotor disk 26, evenly distributed over the circumference. The rotor blades 28 are each inclined to the wind flow direction A by an angle α that is approximately 45°. In the schematic representation of Fig. 1, this angle is indicated between a rotor blade and the rotor shaft 25.

The rotor blades 28 have a constant aircraft wing cross-sectional profile in the radial direction. As shown in Figure 1 for the sake of simplicity on just one rotor blade, this cross-sectional profile has a slightly curved or flat profile surface that is oriented at an angle to the wind flow direction A. The rotor casing 29 has the purpose of preventing the radial ejection of the air streams, which has a braking effect on the rotor 12. The width B of each rotor blade 28 is approximately 1/6 to 1/5 of the rotor diameter D.

The width B of the rotor casing is dimensioned such that a braking effect on the rotor caused by air congestion, friction and vortex formation is minimized. At their radial outer end, the rotor blades 28 are attached to an annular rotor casing 29, whose width B is approximately 1/5 to 1/4 of the rotor diameter D. The rotor casing 29 ends, as can be seen from Fig. 1, with the rear edge of the rotor blades 28 in the direction of the wind flow and extends against the

Wind flow direction A beyond the end section 30 of the paraboloid-shaped wind deflector 22.

For the sake of simplicity, the electrical connection lines of the generator and other details not belonging to the subject matter of the invention have been omitted from the schematic representation.

The wind converter 10 according to the invention is particularly suitable for low-wind areas in which a wind speed of 20 to 25 km/h, i.e. approximately 3 km/h, prevails. Due to the inventive conception, the wind converter according to the invention can convert five to six times more energy of the moving air mass at such wind speeds than the currently known two- and three-blade models with the same rotor diameter D. At 20 km/h a prototype of the wind converter according to the invention reached a speed of 200 revolutions per minute.

Due to the intended mounting of the generator housing 11 on the support mast 15 and a length L of the paraboloid-shaped wind deflector body 22, which is approximately 0.7 times the rotor diameter D, a self-adjusting alignment of the wind converter is achieved during operation of the wind converter by utilizing the wind forces in such a way that the paraboloid-shaped wind deflector body 22 automatically aligns itself against the wind flow direction A.

Claims (12)

thrCharacters/yourref. Our reference/our ref P4550 RW/mg DR. ERNST STURM (1951-1980) DR. HORST REINHARD" DIPL-ING. UDO SKUHRA* DIPL-ING. REINHARD WEISE' DR. WERNER BEHNISCH PO BOX 4401 51 FRIEDRICHSTRASSE 31 D-8000 MUNICH 40 TELEPHONE: 089/3816100 TELEX :5212839isard FAX : 089/34014 79 Date July 22, 1993 Applicant: Med. univ. Dr. Hans Mölzer Tummelplatz 6/3/8 A-8010 Graz
Austria WIND CONVERTERS, ESPECIALLY FOR WEAK WIND AREAS PROTECTION CLAIMS 1. Wind converter (10), particularly for low-wind areas, consisting of a generator housing (11), a rotor (12) which is mounted on a rotor shaft (25) which is rotatably mounted in the generator housing (11) and which is connected to a generator (18), the rotor (12) having rotor blades (28) which are inclined to the wind flow direction (A) and which are connected to an annular rotor casing (29), and !SARPATENT» a bearing device (13) via which the generator housing (11) can be pivoted about an axis of rotation (14) running perpendicular to the rotor shaft (25),
characterized,
that the generator housing (11) is designed as a paraboloid-shaped wind deflector body (22, 23, 30) which is arranged in front of the rotor (12) in the direction of wind flow (A) and whose diameter widens to approximately 3/7 of the rotor diameter (D) towards the rotor (12). 2. Wind converter according to claim 1, characterized in that the length (L) of the paraboloid-shaped wind deflector body (22, 23, 30) is approximately 0.7 times the rotor diameter (D). 3. Wind converter according to claim 1 or 2, characterized in that the wind deflector body (22) has wind deflector elements (22) on its surface, which extend in a straight line from the region of its crest (23) to its end region (30). 4. Wind converter according to one of the preceding claims, characterized in that the annular rotor casing (29) extends against the wind flow direction (29) from the end of the rotor blades (28) attached thereto to over the end region (30) of the wind deflector body (22). 5. Wind converter according to one of the preceding claims, characterized in that the width (B) of the annular rotor casing (29) is approximately 1/5 to 1/4 of the rotor diameter (D). 6. Wind converter according to one of the preceding claims, characterized in that the rotor blades (28) have a constant aircraft wing cross-sectional profile in the radial direction. 7. Wind converter according to one of the preceding claims, characterized in that the width (b) of each rotor blade (28) is approximately 1/6 to 1/5 of the rotor diameter (D). 8. Wind converter according to claim 6 or 7, characterized in that the rotor blades (28) are inclined to the wind flow direction (A) by an angle (α) of approximately 45°, with the less curved or flat profile surface being oriented against the wind flow direction (A). 9. Wind converter according to one of the preceding claims, characterized in that the rotor (12) has 16 rotor blades (28). 10. Wind converter according to one of the preceding claims, characterized in that the rotor blades (28) are attached to a central rotor disk (26) whose diameter (d) is approximately 3/7 of the rotor diameter (D). 11. Wind converter according to one of claims 3 to 10, characterized in that 16 wind deflector elements (24) are evenly distributed over the surface of the wind deflector body (22). 12. Wind converter according to one of claims 3 to 11, characterized in that the wind deflector elements (24) are formed as longitudinal grooves in the wind deflector body (22).