DE3724183A1 - Wind power station - Google Patents

Abstract

The invention is intended to show that two wind wheels (1, 2) mounted one behind the other on a main drive shaft [lacuna] and with the help of a storage battery that is supplied partly from a solar cell (3 m @ 9 m = 900 watts) and partly from the electricity generated in the plant itself. With the help of this storage battery, a geared motor is started up when the wind begins to pick up; its task is to overcome the friction losses in the bearings initially, during the first few rotations (starting aid). Mounted on a tall steel framework. The winds come at any time and from any direction, are intercepted and converted into power immediately. The power is reinforced by a contrarotating wind turbine turned by the wind that runs in the plant inside the steel framework, with a horizontal wind turbine wheel mounted below it. The power generated by the wind there is supplied to the horizontal main drive shaft above via a vertical drive shaft and a bevel gear unit, and converted into electrical energy.

Description

Herewith register is invention described below and he try to grant a patent on it.

Function and description of the system

My wind power plant developed and constructed by me two consecutively mounted wind turbine wheels of the same size a main drive shaft moving back and forth from the wind with their rotation three staged generators can be driven and should generate electricity.

The wind power plant, or its construction, is divided into groups. Each group begins with item 1 .

Group 1

It includes the head of the wind turbine pos. 1 to pos. 27 with two wind turbine wheels of the same size mounted one behind the other on a drive shaft, each with four wind blades.

Group 2

It includes the main drive shaft with the gearbox item 1 to item 131 which can be automatically controlled by the winch depending on the wind strength.

Group 3

It includes the counter-rotating wind vane turbine and the wind vane wheel pos. 67 running in a horizontal position underneath, which are connected in parallel to the main drive shaft and there help to turn the wind vane wheels to the generators pos. 65 , pos. 66 and pos. 64 to generate electricity.

Function and construction of the system

For the time being, the wind power plant is not directly coupled to one of the three generators. It runs empty with the wind until a certain wind speed has pushed the wind impeller with the main drive shaft item 1 from group 2 via the pressure spring item 3 group 2 until the gearbox item 66 with the auxiliary shaft item. 40 in the first and smallest generator, item 64 .

The counter-rotating wind vane turbine item 58 runs continuously when the winds blow strong enough and thus also supports with its power via the gearbox item 13 and item 14 in group 3 and with the transmission shafts item 11 , item 107 and item 127 the main drive shaft pos. 1 and helps to rotate the generator pos. 64 together.

If the wind gets a little stronger, i.e. its speed increases, then the wind impeller Item 26 and Item 8, which are still covering the entire area, will be in succession from the pressure of the wind on the four wind vanes via the compression spring Item 3 in Group 2 et which is pushed further back until the bolt item 4 in group 2 has reached the lever arm item 4 in group 1. (The stop pin item 4 in group 2 is adjustable.) At that moment the auxiliary shaft item 40 switched on the second, the larger generator item 65 . Now the wind impeller pos. 26 and pos. 8 turn the two generators pos. 64 and pos. 65 with the help of the counter-rotating wind vane turbine.

The counter-rotating wind vane turbine pos. 58 is installed on the left side of the system, has eight wind vanes per surface of 900 square centimeters of attack surface and runs to the left. So counterclockwise. The wind shield "W" is attached at the top, the wind tunnel "K" is the wind flow at the bottom.

The wind vane turbine pos. 58 installed on the right of the system also has eight wind vanes, each 900 square centimeters, and it runs to the right. So clockwise. Your wind tunnel "K" is the wind flow at the top and the wind shield "W" is at the bottom.

If the wind is now measured even more strongly around 8.0 to 10.8 m / s according to the Beaufort wind force scale with the anemometer conversion factor 1 m / s = 3.6 km / h. then the two wind vane wheels pos. 26 and pos. 8 still connected one behind the other will move further back and thereby take the lever arm pos . 4 in group 1 to which the two coupling bolts pos. 23 are mounted. Characterized the two coupling pin Pos. 23 19 in Group 1 impeller in the Windflügelrad Pos. 8 in and the coupling pin Pos. From the wind Pos. 8 pushed up to the mark "A" in Grup pe 1 between the two wind vanes Pos. 26 and item 8 . There the coupling pin item 19 disengages from the wind impeller item 8 . The wind impeller Item 8 and the wind impeller Item 26 now do the following at the "A" mark. They disengage themselves there, are independent for a while. The wind vane wheel item 26 is rotated further by the winch for a moment and the two wind vane wheels item 26 and item 8 move by 45 degrees via the two deep groove ball bearings item 15 and item 18 . In the meantime, the coupling bolt item 23 in the wind impeller item 26 has switched on again. Both wind impellers are firmly connected again by the coupling. What happened. The coupling bolts item 19 have switched off from the wind impeller item 8 at the marking "A" and the wind impeller item 26 has shifted 45 degrees over the two deep groove ball bearings item 15 and item 18 and the coupling pin item. 23 has firmly engaged in the impeller Item 26 .

Both wind vane wheels run again together with the difference that the wind can now exert its power not only on four but on eight wind vanes item 25 and item 3 . The wind impellers pos. 26 and pos. 8 have now increased their output almost twice.

The counter-rotating wind vane turbine with its wind vane pos. 58 and the wind vane wheel pos. 67 rotating below it in horizontal position should not be despised, because they have been running from the start and are now helping all three generators to generate electricity produce.

The bearing of the main drive shaft item 1 in group 2 in the housing item 10 is as follows.

The two bearing shells pos. 12 and pos. 15 in group 2 enclose a "Star" ball bushing pos. 14 which are screwed together with the two pin screws pos. 13 in the two bearing shells pos. 12 and pos. 15 , so that it runs with the main drive shaft Pos. 1 . The "Star" ball bushings are only there in that only the main drive shaft, the auxiliary shaft item 40 and the auxiliary shaft item 40 a can be moved back and forth.

The bearing of the main drive shaft in the inner ring of the grooves ball bearing is a loose sliding guide.

Claims (10)

1. Wind power plant, characterized in that it consists of two equally sized wind vane wheels Pos. 26 and Pos. 8 , each with four wind vanes which are mounted on a main drive shaft Pos. 1 and all wind vanes must initially be exactly the same area behind each other. 2. Wind power plant according to claim 1, characterized in that the main drive shaft Pos. 1 is additionally driven by a counter-rotating wind turbine. 3. Wind power plant according to claim 1, characterized in that under the wind turbine still an additional horizontally mounted wind paddle pos. 67 for increasing the torque on the main drive shaft runs from the beginning. 4. Wind power plant according to claim 1, characterized in that in the wind impeller pos. 26, the pos. 10 and pos. 12 for receiving and functioning of the automatic switching by the wind, a hole which is drilled offset from the front by 180 degrees is available. 5. Wind power plant according to claim 1, characterized in that in each of the two bores there is a switching bolt item 19 and a compression spring item 20 . 6. Wind power plant according to claim 1, characterized in that part 10 in the wheel hub is a deep groove ball bearing for easier switching is built. 7. Wind power plant according to claim 1, characterized in that in the wind vane wheel Pos. 8 and Pos. 7 also for receiving and functioning of the automatic circuit by the wind a hole which is drilled offset by 180 degrees on the front. 8. Wind power plant according to claim 1, characterized in that in each of the two bores, a switching pin, item 23 and a compression spring, item 24, are installed such that when the wind is switched, the two wind vane wheels, item 26 and item 8, are moved by 45 degrees can be. 9. A wind power plant according to claim 1, characterized in that for easy switching of the wind in the wheel hub item 8, a grooved ball bearing item 15 is installed. 10. Wind power plant according to claim 1, characterized in that when the wind gets stronger, about 8.0 to 10.8 m / s measured according to the wind force scale to Beaufort. Conversion factor 1 m / s = 3.6 km / h. Then the two successively connected wind impellers pos. 26 and 8 will move further backwards and thus also the lever arm pos. 4 in group 1, whereupon both coupling bolts pos. 23 into the wheel hub pos. 8 and the clutch 19 out of the wheel hub up to the marking "A" between the two impeller wheels item 26 and item 8 . There the coupling pin item 23 switches off the wind vane wheel item 8 , the wind vane wheel item 26 and the wind vane wheel item 8 now do the following at the marking "A" . They disengage themselves there, are independent as long. The wind vane wheel item 26 is rotated further by the winch and the two wind vane wheels move by 45 degrees via the two deep groove ball bearings item 15 and item 18 . In the meantime, the two clutches have engaged again and the two wheels are firmly connected again.