DE3017357A1 - Hydrodynamic energy converter with power control - has rotor on shaft mounted in brake tank, and has spring-loaded pivoted blades to increase resistance at high speed - Google Patents

Abstract

The hydro-dynamic energy converter is intended for producing thermal energy, using a wind driven turbine driving a vertical shaft (2) with bladed rotor (3). The latter rotates above a bladed stator (5) inside a liquid-filled (4) tank (1). The stator blades project upwards from a stator disc, whilst the rotor blades project downwards from a rotor disc. They are pivoted to that disc about radial axes and are spring- loaded such that, at low speed, they are at an acute angle to the disc in the direction of rotation. When stationary, the rotor to stator distance is at least 30 mm, while at high speed, when the blades are at 90 deg. to the disc, this distance does not exceed 10 to 13 mm.

Description

Designation: hydrodynamic energy converter with integrated

grated power regulation The subject of the invention is a hydrodynamic Energy converter with integrated power control for generating thermal energy from the 'rotational energy of the vertical shaft of a wind turbine, which simultaneously serves as a braking device for the wind turbine at high wind speeds.

The use of wind energy by wind turbines offers itself the combination of a vertical axis wind turbine with a heat generating hydrodynamic one Brake, which is usually designed as a water vortex brake.

The axis of the water vortex brake is here directly or via a Gear connected to the vertical wind turbine acbse.

This conversion of rotational energy into thermal energy possesses compared to the conversion via an electric generator the advantage that a larger Overall efficiency of energy utilization is achieved.

The power of the wind turbine as well as the water vortex brake power increases with the third power of the speed of rotation, so that with corresponding Dimensioning and translation the optimal high speed number # = R (C) / V which the ratio of peripheral speed to wind speed.

Usually the wind turbines are strength-wise for box reasons designed so that a braking of the turbine at very high wind speeds is necessary to ensure the storm safety of the plant.

When combining the wind turbine, preferably a turbine of the Darrieus-Tym, with a water vortex brake, it is advisable to use the braking device directly to couple with the heat-generating water vortex brake, in the Way, that the turbine is minimally loaded during start-up, at high wind speeds but complies with a maximum performance limit.

A method is known in which by moving the entire ; Stator or rotor axis the characteristic curve of the water vortex brake is changed to to achieve the desired braking effect. However, the axis must be externally, manually, motorized or by a control mechanism controlled by the wind turbine can be operated, which means additional effort. With a different concept a hydrodynamic braking device for wind turbines sucks in the form of a pump Brake rotor brake fluid from a reservoir into the brake reservoir, so that at additional braking devices due to the rising fluid level are flooded, which brake the rotor shaft. The disadvantage here is the additional one Container for the reservoir, as well as possible noise and cavitation problems with: not completely over-; flooded braking devices.

The invention is based on the object of using a method that avoids these disadvantages. The method of the invention is based on the fact that the Rotor blades of the water vortex brake with increasing speed of rotation the resistance of the water exerted on them can be adjusted so that they at high wind speeds or

RPMs generate the greatest water resistance, whereby the Number of turbines is reduced.

The resistance of the water changes in contrast to the performance the water vortex brake with the second power of the speed of rotation.

The additional braking effect at high wind speeds is according to the invention causes the resistance surface with increasing speed the Rot'pr: vane is enlarged and at the same time the rotor / stator distance is reduced will;. t The reduction in the distance provides the greater braking effect. The minimum Distance is approx. 10mm for rotor diameter from 300mm to 500mm, and wings: from 30mm to 60mm.

You @ ch adjusting the rotor blades would reduce the braking power at constant speed depending on the embodiment of the eddy brake unit by a maximum 400% increase.

The advantages of the method can be described as follows: - Heat generation and power control via the rotor / stator system - waiver or simplification of additional control devices - small starting torque, so that starting devices are reduced in size or not required.

- Change in braking power by a maximum of 400% at constant speed - Low material and construction costs with little signs of wear; decreased Cavitation and noise problems (about 400 mm of brake fluid should be above the rotor stand).

- Avoidance of additional flange connections for control devices on the brake tank with leakage problems.

The invention is explained with reference to the following drawings.

It is shown in: FIG. 1: Cross section through an exemplary embodiment of a hydrodynamic energy converter according to the invention with integrated power control.

Fig. 2: embodiment of the rotor of the hydrodynamic energy converter with integrated power control - top view.

Fig. 3: Embodiment of the rotor of the hydrodynamic energy converter with integrated power control at standstill - side view.

4: Embodiment of the rotor of the hydrodynamic energy converter with integrated power control at high rotational speeds.

Fig. 5: Qualitative operating characteristics of the braking performance of the hydrodynamic Energy converter with integrated power control.

In the brake tank (1), which is filled with the brake fluid (4), preferably water, is filled, there is the vertical R @ t @ rwelle (2), which with the help of the bearings (7), (8) is held.

With the rotor shaft, the rotor (j) rotates above the permanently installed one Stator (5) which is anchored to the bracket (6).

In this exemplary embodiment, the rotor (3) consists of a disk (t10), under which the rotor blades (11) over strong Grlenke (14) over the long side are movably arranged. At a standstill, the wings (11) are lifted by the springs' (15) held in an initial position (12), in which the wings (11) with the Disc (10) form an acute angle in the direction of rotation of the disc.

At the beginning of the rotation, the wing areas therefore have a small area Water resistance.

The braking power remains at low rotational speeds least as the rotor / stator distance is still relatively large. At, higher rotation the heat output increases, but the resistance of the water is still sufficient not enough to push the rotor surface significantly out of the starting position.

Only from a certain speed of rotation do the rotor blades due to the increasing resistance of the water in the position (15) of the maximum Rash pressed, which are not exceeded due to a locking device can.

In this position the water has the greatest resistance held against7, the distance between rotor and stator is the smallest. By now increased Braking power is the wind turbine from the range of maximum power output and thus maximum wind load led to lower loads.

The number of revolutions at which the maximum deflection of the rotor blades is set here by the dimensioning and design of the return springs (13) given for a given rotor and brake geometry.

The one generated by the rotor / stator system in every operating state Heat output is taken from the heat exchanger (9) and fed to the consumer.

In point (5) the operational characteristics of the Braking power of the hydrodynamic energy converter, where the characteristic curve (q) is at a rotor with the minimum deflection of the rotor blades kept constant, and characteristic curve (2) at maximum deflection the rotor blades would set.

Another design of the rotor is possible without a qualitative one Change in operating characteristics occurs.

Instead of using tension springs, the rotor blades (1 can use torsion springs are held in position with the spring axes parallel to the axis of the Joints (14) are aligned A rotor configuration is also useful when which the plugs and feathers are not on a disc (10), but on a star shape around the rotor shaft (2) arranged beams or rods are attached.

The carriers can be connected at the outer ends by struts.

The carrier configuration is particularly recommended for large rotor diameters.

Additional braking devices can easily be attached to the rotor shaft (2) are provided. It should be noted, however, that these devices in every operating condition are covered by the brake fluid to avoid cavitation problems to be avoided With the disk configuration of the rotor (3), the disk (10) as with conventional rotors with rigid rotor blades with holes of approx. 20mm Diameter between rotor shaft (2) and rotor blades (11) are provided to cine to achieve maximum turbulence of the brake fluid.

L e r s e i t e

Claims (1)

PATENT CLAIMS 1. Hydrodynamic energy converter with integrated Power control with vertical rotor shaft for combination with a wind turbine, characterized in that the rotor shaft (2) is mounted in a brake tank (1), that a rotor (j) is mounted on the rotor shaft (2), which over the brake tank (1) Permanently installed stator (5) rotates that the rotor blades (11) on a shaft with the red shaft (2) Permanently connected disc (10) are attached via joints (14) and by springs (13) are held at a standstill in a starting position (12) in which the The rotor blade (11) and the disk (10) make a sp @@@ en angle in the direction of rotation of the disk (10), and the rotor / stator distance is at least 30mm At high speeds, however, the rotor blades (11) form a right angle with the disk (10), the rotor / stator distance from a maximum of 10mm to 1dmm amounts to. 2. Hydrodynamic energy converter with integrated, integrated contribution control according to claim 1, characterized in that the rotor blades (11) operate at high speeds due to the formation of the joints (14) no greater than a right angle with the disc (10) can form in the direction of rotation. 8. Hydrodynamic energy converter with integrated power control according to claim 2, characterized in that here the rotor blade (11) of more as a spring (13). is held in position. 4. Hydrodynamic energy converter with integrated power control according to claim 3, characterized in that the springs (13) act as torsion springs are trained and with their longitudinal axis (3) parallel to the joint axis of the joints (14) are attached. 5. Hydrodynamic energy converter with integrated power control according to claim 4, characterized in that the disc (10) between the rotor shaft (2) and rotor blades (11) are provided with holes. 6. Hydrodynamic energy converter with integrated power control according to claim 5, characterized. characterized in that the rotor blades (11) and the springs (13) not on a disc (10) but. on arranged in a star shape around the rotor shaft (2) Straps are attached. 7. Hydrodynamic energy converter with integrated power control according to one of claims 1 to 6, characterized in that the rotor shaft (2) additional braking devices are attached, all braking devices are covered with brake fluid.