DE10029011A1 - Wind pressure turbo rotor has parabolic cylinder as leading bow structure in front of circular cylinder to provide extended curved incident flow surface and increase in wind pressure - Google Patents

Abstract

The device has a parabolic cylinder as a leading bow structure in front of a circular cylinder (1) to provide an extended curved incident flow surface and hence to cause an increase in the wind pressure. Analogously to this a rear termination is attached in the form of a parabolic cylinder. The rotor axles (13) protrude upwards and downwards and drive generators (13a).

Description

The invention relates to stationary, vertical cylinders ( 1 ) with an inlet ( 8 ) and outlet slots ( 8 ) on the sides of the cylinders in order to drive a multi-bladed axial rotor ( 3 ) inside in the central axis ( 2 ), which in turn extends the covers ( 12 ), above and below, the rotor axes ( 13 ) each of a generator ( 13 a) to generate electrical energy.

The direct use of wind turbines has been known for ages. Innovations are on Pylons mounted propellers with electrical generators with low efficiency (as usual with aircraft engines), set up in exposed places.

In order to achieve an even better use of the flow velocity, the wind is accelerated around the cylinder curvatures ( 7 ) according to the Bernouillean principle, after which air passing by curved surfaces is accelerated.

A congestion bar ( 9 ) at the inlet slot ( 8 ) additionally creates a jam and increases the pressure effect.

The outlet slot ( 8 ) lies opposite, the air acceleration creates a suction effect ( 10 ) to relieve pressure.

The invention relates to a wind pressure turbo rotor for power generation.

Due to the flow direction (6) to the cylinder (1), the air flow is divided on both sides around the curved cylinder walls (1 u. 7), the inflow speed increases with increase in pressure for the inflow (8) in the inlet slot (8) and by projecting Introduction fence ( 9 ) additional pressure is generated. Compared with the introduction slot (8), the outlet slot (8) for pressure relaxation.

On the back, in the middle of the rotor blades ( 3 ), at right angles to the axis ( 2 ), a rail ( 15 ) with a hooked weight ( 16 ) with a return spring ( 14 ) is to be attached as a centrifugal governor.

In gusty winds, a more moderate circulation is achieved, also by regulating the Slot openings.

The cylinders can be used in exposed areas where the wind flows Street canyons for power generation and ventilation. Likewise in vehicles by the masses of air flowing past the walls to charge batteries to Switch to electric motors in city traffic.

To prevent ice buildup at low temperatures, the curvatures and Inlets can be equipped with an electrical de-icing system, as with Aircraft deicing is common.

Analogous to the construction of the cylinder described above, an increase in the rotor speed will be achieved by coupling two cylinders ( 18 ) side by side.

In FIGS. 1-3, a first embodiment of the invention is described.

A separating fence ( 19 ) in the blowing direction, on the center of both cylinders, divides the air flow on both sides around the curved cylinder walls ( 18 ) into the center of the leg ( 5 ), into the inlet slots ( 8 ) on both sides.

Covering the roof ( 20 ) from the cylinder edges ( 7 ) to the center of the leg creates a hyperbolic box ( 21 ), a pressure gate that generates a dynamic pressure and significantly increases the speeds of the rotors ( 3 ) through the slot inflows ( 22 ).

The air flowing around the outside of the cylinder creates a suction effect at the outlet slots ( 10 ) to relieve the internal pressure.

The axis extensions ( 13 ) then open at the upper and lower cylinder covers ( 12 ) in the rotor axes ( 13 ) of the four generators ( 13 a) for power generation. The cylinder rotors then turn against each other.

In order to operate the system even during a lull, gas heated by gas heating can be blown through the inlet slots ( 22 ) onto the wing surfaces ( 3 ) of the rotors in order to keep the speed of the apparatus in constant revolutions. With ice build-up also possible for de-icing.

A further development would be cylinder and inside, axially rotating rotor into one Dismantle the electric generator in such a way that the rotor generator with appropriate Provide copper windings, and the cylinder inner wall with appropriate Windings, as usual with a stator of an electric generator, with corresponding ones Magnetic rods. Inner pole or outer pole generator.

The apparatus would have to stand on a rotatable base for alignment cheapest blowing direction, according to the weather vane principle.

On a rail circle with several rollers / edges with underhand grip under the wider ones Treads for locking, mechanically and / or with magnetic brake shoes. The entire apparatus then rests on a concrete table.

With reference to FIGS. 4-6 two preferred embodiments of the invention are described, the principle of a "wind pressure turbo rotor" remains unchanged, namely is an axially rotating in a vertical as well as horizontal cylinder turbo rotor with inlet and outlet slots for driving Electric generators provided by wind energy.

FIGS. 4A and 4B show a schematic perspective side view and plan view of an embodiment with a rotor. FIGS. 5 and 6 show respective views of an embodiment with double cylinder.

• 1. By attaching ( Fig. 4) a parabolic cylinder ( 23 ) as a bow stem ( 23 ) in front of the circular cylinder ( 1 ) creates an extended inflow curve surface ( 24 ) and thus an increase in wind pressure. Analogously as a rear end ( 23 ).
• 2. An ellipsoid ( 23 ) is created, which is expanded by one floor ( 25 ) above and below for the installation of the generators ( 13 a). The rotor axes ( 13 ) protrude at the top and bottom, whereby the generators are driven by V-belts and / or bevel gears. A flywheel ( 26 ) with swing-out segments under spring tension is installed between the axle exit ( 13 ) and the gearbox ( 36 ) ( Fig. 6), as an alternative to the wing centrifugal governor ( 14 , 15 , 16 ) ( Fig. 1, 2) for more moderate rotation ,
• 3. A further increase in the rotation is achieved by laying the outlet slot ( 8 ) on the inflow side ( 8 ) after rotation of the rotor ( 3 ) by approximately 290 to 315 degrees, through a channel outlet slot ( 27 ) in the blowing direction, in front of the inlet slot ( 8 ), according to the concentricity principle. In order to avoid turbulence, the introduction bar ( 9 ) must be left out.
• 4.Analogous to the construction of the parabolic cylinder body ( 23 ) described above, a double cylinder body is constructed which, by coupling two cylinders ( 1 ) ( FIGS. 5, 6) side by side, at a distance, with an introduction fence ( 19 ) between the cylinder covers ( 20 ) of the funnel box ( 21 ), is created to absorb and introduce the wind pressure.
• 5. The attached parabolic cylinders as bow stem and rear apron receive - as previously described in Fig. 4 - an analog superstructure and substructure ( 25 ) for installing the generators, with a flow channel ( 26 ) each above and below the funnel covers ( 20 ) free flow of the wind and the passage of foreign bodies.
• 6. The bow stems then receive two hyperboloid stems ( 23 ) with bow tips ( 33 ) offset to the outside in order to obtain a larger inlet gate ( 34 ) and thus an enlarged funnel box ( 21 ). There is an additional co-flow effect to the funnel inflow.
• 7. To smooth the inflow pressure, the inflow gate ( 34 ) from the bow tip ( 33 ) to the bow tip is provided with a louvre grille ( 35 ) - see wind tunnel.
• 8. In strong winds, e.g. B. hurricanes, in order to obtain a stable trigger, the upper cover should preferably be lifted mechanically.

Claims (24)

1. Wind pressure turbo rotor characterized by attaching ( Fig. 4) a parabolic cylinder ( 23 ) as a bow stem ( 23 ) in front of the circular cylinder ( 1 ) to provide an extended inflow curve area ( 24 ) and thus an increase in wind pressure, and analogously a parabolic cylinder is attached as the rear end ( 23 ). 2. Turbo rotor according to one or more of the preceding claims, wherein an ellipsoid ( 23 ) is extended by one floor ( 25 ) above and below for the installation of the generators ( 13 a), the rotor axes ( 13 ) protruding above and below, whereby the generators are driven by V-belts and / or bevel gears. 3. Turbo rotor according to one or more of the preceding claims, wherein a flywheel ( 26 ) with swing-out segments under spring tension is installed between the axis exit ( 13 ) and gear ( 36 ) ( Fig. 6) for more moderate circulation - alternatively to the wing centrifugal governor ( 14 , 15 , 16 ) ( Fig. 1, 2). 4. Turbo rotor according to one or more of the preceding claims, wherein a further increase in rotation is achieved by laying the outlet slot ( 8 ) on the inflow side ( 8 ) after rotation of the rotor ( 3 ) by about 290 to 315 degrees, through a channel outlet slot ( 27 ) in the blowing direction, in front of the inlet slot ( 8 ), according to the concentric principle, the introduction bar ( 9 ) being omitted to avoid turbulence. 5. Wind pressure turbo rotor, whereby analogous to the construction of the parabolic cylinder body ( 23 ) described, a double cylinder body is built up by coupling two cylinders ( 1 ) ( Fig. 5, 6) side by side, at a distance, with an introduction fence ( 19 ) between the Cylinder covers ( 20 ) of the hopper box ( 21 ) are created to absorb and introduce the wind pressure. 6. Turbo rotor according to one or more of the preceding claims, wherein the attached parabolic cylinders as bow stem and rear apron receive an analog superstructure and substructure ( 25 ) for the installation of the generators, with a flow channel ( 26 ) above and below the funnel covers ( 20 ). for the free flow of the wind and the passage of foreign bodies. 7. Turbo rotor according to one or more of the preceding claims, the bow stems then being given two hyperboloid stems ( 23 ) with bow tips ( 33 ) offset to the outside, so as to obtain a larger inlet gate ( 34 ) and thus an enlarged funnel box ( 21 ), so that there is an additional co-flow effect to the funnel flow. 8. Turbo rotor according to one or more of the preceding claims, wherein for smoothing the inflow pressure, the inflow gate ( 34 ) from bow tip ( 33 ) to bow tip with a lamellar grille ( 35 ) - cf. Wind tunnel - is provided. 9. Wind pressure turbo rotor for electrical power generation by multi-bladed turbo rotors, axially rotating in a closed stationary circular cylinder with inlet and outlet slots ( 8 ), driven by wind pressure to drive electric motors, whereby the cylinder curvature produces an acceleration of the wind pressure according to the Bernouillean principle becomes. 10. Turbo rotor according to claim 9, wherein standing in the wind stream stationary, vertical cylinder ( 1 ) with inlet ( 8 ) and outlet slots ( 8 ) on the sides of the cylinder, in the central axis ( 2 ) inside a multi-bladed axial rotor ( 3rd ) drives, which in turn extends, in addition to covers ( 12 ), above and below, the rotor axes ( 13 ) each of a generator ( 13 a) for generating electrical energy. 11. Turbo rotor according to one of the preceding claims, wherein an introduction bar ( 9 ) at the inlet slot ( 8 ) generates a jam and increases the pressure effect. 12. Turbo rotor according to one of the preceding claims, wherein the outlet slot ( 8 ) lies opposite and the air acceleration creates a suction effect ( 10 ) for pressure relief. 13. Turbo rotor according to one of the preceding claims, wherein the inflow direction ( 6 ) on the cylinder ( 1 ), the air flow divides on both sides around the curved cylinder walls (1 and 7), the inflow speed increasing, with pressure increase for inflow ( 8th ) into the inlet slot ( 8 ), an additional pressure being generated by the incoming inlet fence ( 9 ). 14. Turbo rotor according to one of the preceding claims, wherein on the back, in the middle of the rotor blades ( 3 ), at right angles to the axis ( 2 ), a rail ( 15 ) with hooked weight ( 16 ), with return spring ( 14 ), attached as a centrifugal governor is. 15. Turbo rotor according to one of the preceding claims, in which the cylinders in exposed places, in street canyons through which wind flows Power generation and ventilation, also in vehicles by on the walls passing air masses to charge batteries, to switch to Electric motors are used in city traffic. 16. Turbo rotor according to one of the preceding claims, in which, to prevent ice build-up at low temperatures, the curvatures and enemas be provided with an electrical defrosting system. 17. Turbo rotor according to one of the preceding claims, wherein an increase in the rotor speed can be achieved by coupling two cylinders ( 18 ) side by side. 18. Turbo rotor according to one of the preceding claims, wherein, through a separating fence ( 19 ) in the blowing direction, on the center of both cylinders, the air flow on both sides around the curved cylinder walls ( 18 ) in the leg center ( 5 ), in the bilateral inlet slots ( 8 ) Splits. 19. Turbo rotor according to one of the preceding claims, wherein, by covering the roof ( 20 ) from the cylinder edges ( 7 ) to the center of the leg, a hyperbolic box ( 21 ), a pressure gate, is created, which generates a dynamic pressure and the speed of the rotors ( 3 ) significantly increased by the slot inflows ( 22 ). 20. Turbo rotor according to one of the preceding claims, wherein, on the outside around the cylinder flowing air at the outlet slots ( 10 ) generates a suction effect to relieve the internal pressure. 21. Turbo rotor according to one of the preceding claims, wherein the axis extensions ( 13 ), on the upper and lower cylinder covers ( 12 ) in the rotor axes ( 2 ) of the four generators ( 13 a) open to generate electricity. 22. Turbo rotor according to one of the preceding claims, wherein the system can also be operated during a doldrums, wherein gas heated by gas heating is blown via the inlet slots ( 22 ) on the wing surfaces ( 3 ) of the rotors, so that the speed of the apparatus in uniform Keep turns. 23. Turbo rotor according to one of the preceding claims, in which the cylinder and the inside, axially rotating rotor, to an electrical generator is developed in such a way that the cylinder inner wall also with corresponding Windings is provided with, as is usual with a stator of an electric generator corresponding magnetic rods (inner or outer pole generator). 24. Turbo rotor according to one of the preceding claims, in which this on a rotating base stands for alignment in the cheapest Blowing direction, according to the weather vane principle.