DE4317004A1 - Wind turbine - Google Patents

Abstract

Driven by an artificially generated vortex wind (whirlwind, turbulent wind, eddying wind). Capturing the air produces an atmospheric overpressure around the vortex chamber. On the other side, sucking out produces a suction reaching into the vortex chamber. The air can flow through the nozzles at increased speed. This produces in the drum power vortex wind or even a storm, which we need to drive the rotor. When used on dike dams in the north sea, it would simultaneously be possible to hold relatively large storm tides (storm floods) at bay, and have the best wind. It would also be possible to combine a plurality of rotors by means of couplings to form a larger powerhouse. Scientists maintain that the sun supplies us with ten thousand times more energy than we humans require. So let's get down to it and make use of some of this energy; in so doing we will be kind to the environment and create new jobs. <IMAGE>

Description

The invention relates to a wind turbine.

I put the turbine in an artificially generated one whirlwind. We set up smaller plants a mast. Where they feel like a windsock in the correct wind direction.

By drawing FIGS. 1 and 2. Fig. 1 is a plan view and the FIG. 2 shows the side view. No. 1 is the storage space, No. 2 are the injection nozzles, No. 3 is the swirl chamber, No. 4 are the suction shafts, which are located in the middle of the swirl chamber, below and above. Rotor No. 5 sits in the swirl chamber and has the shape of a double T. Because the vortex force subsides to the suction shaft. Below I pulled the shaft through the extraction shaft where we can connect a power generator. I indicated a wave further to the injection opening. In this area we can hang up the device. So it always stands in the right wind like a windsock. It is particularly important that the injection nozzles must have the smallest cross-section of the entire system. A smaller cross-section can often generate higher swirl speeds. The extraction shafts definitely need a much larger cross-section. Sucked air expands and swirled air needs a larger cross section.

Now as a large system

In a stationary system you could easily Rotors two or four meters in diameter deploy. Could you still on the dike dam to use the North Sea would be different whose flies are caught in one fell swoop. First some dangerous storm surge could affect our coasts do nothing more. Second, over the dike dams the best wind is known to blow. Third comes still quite a lot of energy.

The drawing Fig. 3 is a plan view in section. Fig. 4 seen from the sea side. The easiest way to cast such stationary large-scale plants is from concrete. Whirl chamber with rotor is later simply inserted from above, seals everything well, and puts a lid on it.

Shaft 1 is the inlet shaft or pressure chamber, which is connected to the space around the swirl chamber by a connecting opening. Now the compressed air can only get into the swirl chamber via the blowing nozzles No. 2 . The injection nozzles are best seen on the part drawing Fig. 5 at the swirl chamber. Is to the right and left of the swirl chamber of the suction chamber connected to the suction shaft no. 4th Where I drew a door from the land side because of the maintenance work. In the extraction rooms, the rotors can now be connected with couplings, as shown in the right extraction room. Or we can insert a generator into the extraction room, as shown on the left.

Now briefly to the individual parts Fig. 5, 6, 7 and 8th

Fig. 5 shows again the swirl chamber, seen from the right side with the blowing nozzles No. 2 , again only four nozzles. More can also be used, only the cross-section of the nozzles has to be adapted to the given conditions in each system. Less nozzle cross-section can often bring more vortex speed.

Fig. 6 we saw the rotor again from the front and the front.

Fig. 7 is the blowing screen, which is provided with a square plate below, with which we attach it to the blowing shaft No. 1 . The injection screen is attached to a construction at the top center with a ball bearing. Below are three guide rollers that run around a hoop. Which means that the blow-in umbrella always turns in the right wind. Fig. 8 is the suction hood, which, like the blow-in screen, automatically sets itself in the right direction wind. The suction hood is attached to the suction shaft no. 4 with the lower plate. With correct nozzle metering, there must be an atmospheric overpressure before the vortex chamber. On the other side there must be suction up to the vortex chamber. This is how we get the greatest possible swirl speed.

I would be very happy to herewith a small one To be able to take a step towards energy generation.

Claims (7)

1. Wind turbine, characterized in that it is driven by an artificially generated whirlwind. 2. We can mount smaller wind turbines on a mast ren, characterized in that they themselves in the set the correct wind direction. 3. On larger systems, we load the systems with large wind trap screens. On the other hand, we suck the air out with large extraction hoods.
Characterized in that the blowing and suction hoods automatically set in the right wind. 4. In the vortex chamber, the injection nozzles bring in the air a whirlwind, characterized by the wind trap there is an atmospheric overpressure in front of the vortex chamber on the other hand, suction creates suction hood into the swirl chamber. Through the nozzles the air is pressed and sucked with excessive pressure. This is how we create the whirlwind. 5. For large systems on the North Sea on the dike dams we can do different good things characterized in that a major storm surge does not more about the dikes. 6. Characterized in that the best over the dikes Wind blows, which benefits the generation of electricity. 7. On a straight line, where several rotors in a row stand, characterized, we can several Ro Connect gates with one another using couplings, so get we had a bigger muscle man for bigger genera goals.