DE3030425A1 - Construction of wind plants in coastal regions - suspending Magnus rotor by ball joint from four-limbed support structure - Google Patents

Abstract

The wind generator, consists of a Magnus rotor, supported on a non-rotating axis which, in turn, is held by four steel pillars. The centre axis of the rotor has a ball-shaped upper end, which may be fixed with or without bearings in a cup-shaped recess at the top of the supporting structure. The latter is strong enough to withstand large pressures and storm forces without oscillating or deflecting. The rotor itself is made from steel sheet or polyester with glass fibre reinforcement. The extension of the central axis at ground level is let into a notch which has reinforced side walls, in order to transfer the rotation of the axis due to precession, to the generator. Thus, the base of the central axis can slide into the centre or the periphery of the disc, depending on the prevailing wind pressure. By using a Magnus rotor, and building the wind generator on the coast on high ground, a cheaper installation with a higher efficiency than a conventional wind propeller, can be produced.

Description

"Process for the production of wind turbines near the coast" The Ilamburger Electricity works at the end of the year with the construction of the wind farm G r o v i a Start n 1, a 150 m high tower with wind propellers with a cross section of loo m It should be used at wind speeds of 5 - 10 m / sec. an output of 3 megawatts at a cost of DM 50 million. Close to the coast is always the required wind up to 10 m / sec. vorha @ However, one would be for a performance Power plant of loo -1300 megawatts e.g. the power plant in Stade 200 of these wind turbines at a cost of lo billion DM required Perhaps it would be too consider whether the same effect could not be achieved with less resources An iagnus rotor of 5. m. diameter and 20 m height also use this if you are on a hill or a Dühne builds, even if the win speed is a little slower, like at a height of 150 m. The efficiency of a wind propeller can also be determined using the profiling curves can hardly be named @ with 50%, and that of a Magn @ s rotor with 80%, close by the effect of sails, this being about 3 - 4 times the cross-section how your own can be of use.

Perhaps the wear of a Magnus rotor would be somewhat greater, wi b @ i a wind propeller, but this must always be drchen, dä @ s at 100 m cross-section in 150 m. Height, which the Magn @ s rotor does not need, there It works equally well in every wind direction. It would certainly also be possible to use Magnus rotors from 30 @ 40 m. Build height and also with a larger cross-section, so that a higher wind cross-section, as used in the loo m propeller.

Apart from that, a Magnus rotor system would be about 10 times as large cheaper than the 150 m i'urm. Perhaps the construction price could be reduced even more , so that a magnetic rotor system will be fully amortized in about lo years and then Generates profit; A @@ @agnusroter @@ a @@ ch is suggested not to be arranged with the rotating axis, the @ lek @ omotor @@@ @otation @nd the 3 times Wall speed z m resp. @@ nd @@ @@@ er / seconds via a Win @ knife to steer automatically and to be arranged at the top at the top. There are 4 branches around the rotor e.g. high-voltage pylons or iron constructions, as well as Be @ on or @ isenbeton- @ feiler be arranged at the same height on a foundation and with cross connections in the The height at which the axis of the Magnus rotor does not rotate is hinged in a ball joint with or without ball or roller bearings, so that the Magnusroter can commute freely in all @ichings.

The upper ball joint, the struts and the two or 4 branches an iron crown so ia be so stable that the Magnus rotor is also tall Withstands wind speeds, and in the event of a storm the rotary electric motor automatically is turned off by controlling the anemometer.

The height of the rotor can be lo, 2om or even more, depending on the greetings of the 4 supporting iron constrictions, and the diameter 7, 5, or also more ladder At the lower end of the rotor, the non-rotating pretty one is somewhat elongated and opens into the gap of a power transmission disk Generates Magnus effect, which moves the rotor to one side, but there the rotor hangs firmly in the bearing at the top, it is slightly oblique as a result of the rotation of the Rotor creates a gyroscopic effect or

a precision so that the lower axis describes an arc of a circle The force and the size of this circular arc depend solely on the data of the Magnus rotor and the respective wind speed from so that all the wind power on the precession movement is transmitted.

Depending on these sizes, the axis can be in the gap of the coupling washer wander back and forth and describe a small or a larger circle. , also more or less force on the power generator located under the pane transfer .

A small formation of a Magnus rotor of 5 m. Diameter @ e @ and A height of 20 m would use about 300 n wind space, and not like a profiled propel. he with 35, J but a bit with 80, J efficiency.

The Magnus rotor could generate 3 - 6 megawatts, depending on the wind force and also with an iron construction of 20. - 30 m above sea level to produce a lot of electricity that a profit could be made after a few years The Magnus rotor itself could be made of sheet steel or polyester with fiberglass and overlaid Ball bearings are often attached to the non-rotating axis and with a internal electric motor are operated. The anemometer chew on the upper iron structure via electrical impulses the drive current of the upper electric motor always steer to 3 times the wall speed of the respective wind speed In the event of a storm, the E. engine would have to be switched off and the lower axle not rotating Blocked On the sea, the Magnus rotor could be on higher dunes or on a line Hills can be installed, but also on the roofs of higher houses to ensure heating in addition to household electricity, but only in windy areas Areas, especially at the sea and on the islands.

In the attached sketch the load-bearing iron construction is marked with 4 Support pillars only hinted at, also the upper load-bearing connection between Masts.

The ball joint with or without roller bearings is at the end of the non-.

rotating axis attached or. this narrowed there .. The upper one Steel structure must be so stable, and larger pressure differences and also Withstand storms without bending ode to great vibrations.

The rotor wall is made of sheet steel or polyester with glass fibers manufactured, also the rotor edge disks. On the bottom is the extension of the non-rotating axis in a notch with reinforced side walls - similar a sliding piston - embedded around the rotation of the axis as a result of the precession to transfer to the generator In the inheritance the sliding piston can be the non-rotating axis slide into the center of the disc or into the perepheria, depending on which There is wind pressure and changes the precession circle.

The sliding piston and the side reinforced notch - which are different Shapes - curves or straight lines - is made possible by a self-acting lubricating oil supply oiled. The side reinforcements of the notch can also be equipped with a roller bearing in order to reduce friction, others in the technology \ acquaintance Device to reduce frictional resistance and wear in power transmission the sliding piston on the extended rotor axis, and the side rollers in the Side reinforcement of the notch on the dimensional disc for power transmission to the Generator verX; ends to be The transmission disk is curved about.s so that the should be able to swing freely in the notch, and be very well designed as a flywheel and regulator to serve a uniform power transmission to the generator all Bearings: such as the upper ball joint with rollers or ball bearings, all ball and roller bearings on the non-rotating axle and the storage of the power transmission from the precession movement, can be done automatically by a central ul supply be lubricated, e.g. by attaching thermocouples to each bearing to switch on the oil supply at the slightest change.

At the end of the sketch on the left is roughly the arrangement of the iron structures with the upper load-bearing connections and the Magnus rotor drawn in, right again the precession movement of the rotor on a circular path with coarser systems the lower power transmission can also be used in a different manner known in the art Form, because then looo de ps. Or kilowatts have to be transferred . E.g. also gear wheels with a regulating laboratory based on the principle of the old steam engines Stable around the scope of the precision movement with every application of force or change in wind to keep.

But even with smaller systems, the precession movement is slow so that a translation can be inserted in front of the generator, in order to comply with the required number of doors for the respective generator Im Otherwise, components can be used that are known and manufactured in the industry e.g. the oil supply, the gearboxes e.g. of trucks, the bearings from the aviation industry.

and the Rptoren made from existing large diameter steel tubes like the iron constructions of the support masts of the overhead lines. Only the respective one Power transmission of the precession motion to the generator could be for smaller and larger standardized for larger systems It should also be mentioned that the system will rain - and must be built snow-tight to prevent corrosion and the operation as is possible in midsummer as well as in winter at very low temperatures

Claims (1)

is a process for the manufacture of wind turbines near the sea P a t e n t a n s p r ü c h e. 0 Process for the production of plants close to the sea, thereby characterized that a Magnus rotor on 4 iragm masts made of iron structures such as the masts of the @berlabdleitung or in Stah @ eton with an upper steel strut on a ball joint or as a ball end in a hemispherical shell of the non-rotating one The rotor axis rises in the same direction and can swing freely on the upper part of the rotor the electric motor, which leads to a 3-fold orbit speed of the rotor wall to the respective wind speed by an electronic control from one Anemometer is controlled, arranged and connected to the cylinder wall from the inside is, and the lower end of the non-rotating shaft designed as a sliding piston in a solid, spherically curved surface @ in @ a notch, with side walls provided with roller bearings, can slide back and forth, according to the respective Precession circle of the rotor, and the disc rotates over a Gear drives the power generator, or to maintain an always the same size Precession circle is provided with a regulator in the style of steam engines , or designed as a flywheel so heavy and massive that a constant ltotation also keeps the precession circle on the same track, with all being lean , the upper ball bearing or ball joint, all roller bearings on the axis of the rotor and the sliding piston in the roller bearing of the notch in the flywheel by an automatic Oil supply to fia-nd from @ herm @ elements arranged on the bearings, lubricated 2. The method according to claim 1, characterized in that the Magnus rotors can also be arranged the other way around in the system and the precession circle is on top and also there the power generator, 3. The method according to claim 1 and 2, characterized that the rotary electric motor and the lower power transmission pulley are switched off in the event of a storm or the flywheel is tightened with brake pads 4. Procedure according to claim 1, 2,3, characterized in that; the system is storm-proof