DE102007049590A1 - Three or four-laminated vertical wind turbine e.g. Savonius turbine, for producing current to be supplied to e.g. private house in city, has blades terminated on inner-circle of larger radius, where larger openings are formed for wind flow - Google Patents

Abstract

The turbine has three or four cylinder barrel-shaped blades (2), where the blades are arranged at a same distance from each other with outer edges on an outer circle on a lower disk (1) and/or on the outer circle of an upper disk. The blades are truncated from inner edges about one eighth of a half-shell. The blades are not terminated in a small, concentric internal circle of the lower and upper disks, and are terminated on an inner-circle (4) with larger radius, where larger openings are created for the wind flow.

Description

As I read and found out, the story begins Vertical turbine with curved Shovels with Fausto Veranzio, who in 1551 in Sebenico in Dalmatia was born. He designed in 1610 a vertical turbine with vertical Axis and curved Blades. His ideas have been taken over by others. Not least of that Finnish ship captain lieutenant Sigurd Savonius, who invented the well-known Savonius rotor.

at the Savonius turbine hits the wind to the first cylindrical concave, the wind-facing half shell, passes through from there the middle to the concave half-shell mounted in the opposite direction. The wind is thus deflected by the middle to the opposite Half shell, from which the wind is deflected again and can flow outwards. For this reason, the Savonius turbine has no shaft in the middle, because a wave in the center of this turbine hinder the wind would and affected the speed of the turbine.

The applies to all vertical wind turbines.

My Vertical wind turbine has three or four wings (blades) opposite the two wings of the Savonius wind turbine.

Even though the Savonius turbine starts up easily low winds, it has the disadvantage that the force of the wind, the meets the first shell, is larger as the transmission of the wind on the opposite standing second shell, with the result that this turbine does not run evenly, they to reinforced Fluttering and uneven turning tips and producing a flap sound, especially if she's running fast.

Thereby the vertical turbine developed by me has three or even four leaves, the rotational movement becomes more regular and noiseless. This property wants I exploit. Because my aspiration is that on every house in the city or in villages A vertical turbine is installed which generates electricity for private use Households or for the community.

Of the Padding of the leaves in the central region of the Savonius turbine is sized so that the shells to run into it and a measured gap in the interior of the turbine between the two shells as a nozzle serves the air pressed in the opposite lying concave shell transmits.

In 1a , Plan of the Savonius turbine, is the most favorable run of the turbine in the direct wind direction. If the shell 01 90 degrees, and the shell 02 also rotated 90 degrees and lies in the wind direction, creates a negative position of the Savonius turbine. The shell would have to run another 45 degrees to get wind pressure. Had it not been for the Magnus effect, the turbine would have stopped. The flap sound then arises when the shell 02 finally fully concave is applied.

This Circumstance is excluded in my three- and four-bladed turbines.

In 1 the plan of the four-bladed turbine is shown. The wind in the four-bladed construction comes simultaneously through two wind inlets ( 3 ), and therefore it is also used by two wind outlets ( 3a ) let out. Inside, my turbine has no wave. This interior ( 4 ) is larger than the Savonius turbine because the semicircular baseline of each cylinder shell-shaped blade (FIG. 2 ) is shortened from the inside so that the blade is not on a small concentric inner circle ( 4a ), but on an inner circle ( 4 ) with a larger radius. The openings created thereby for the Winddurchfluß are necessary. The semicircularity of the blades is abandoned. It is cut off from the inner part of the scoop about one-eighth of the half-circle. The thus enlarged interior of my turbine firstly prevents obstruction of the wind flow and secondly leads to a compression of the wind in the interior by the rotation of the turbine and the co-rotation of the wind.

Of the Advantage of my four-winged Turbine opposite the Savonius turbine lies now in the fact that the Savonius turbine runs slightly faster in strong wind, my Turbine but starts in a low wind and runs continuously, and also then continue to run evenly, though in a doldrums the Savonius stops.

I have provided that under the disc ( 1 ) four flat containers ( 6 ), in the form of the space between the blades, which are half filled with viscous fluid. The space of the containers has the name ( 6 ). See also 1c , When the turbine stops, the viscous liquid spreads to the bottom of the containers ( 6 ). When the turbine starts to run, the viscous fluid immediately starts to flow to the outer edges of each container ( 6 ) to run. When running the liquid, it must overcome an inclined (about 30 degrees inclined) attached separation dam in each container. This dam is sized so that all the liquid can collect in the outer rim of each container. In the inner edge of the dam there is at one point a narrow passage in the whole height of the dam, so that in case the turbine starts to run slowly or is about to stop, the liquid slowly escapes from this narrow passage back to spread again on the entire bottom of the container. When the wind starts again, the turbine will not be hindered from starting again easily. The jammed liquid at the edge helps to synchronize and fast-run the turbine. The centrifugal force is used to overcome fluctuations in the wind (gusts).

At the center of the disc ( 1 ) below the disc is the attachment of the shaft ( 5 ) for centering the system and the connection to the electricity generator.

The three-bladed turbine surpasses all turbines in terms of speed. It surpasses the Savonius turbine in speed by 100 percent. The reason for this is that the turbine has two air inlets ( 3 ) and only one air outlet ( 3a ) owns. The three-winged turbine is shown in plan in the 1b ,

The semicircular shape of the baseline of the cylinder jacket-shaped blades ( 2 ) is also abandoned here. It is cut off from the inner part of the scoop about one-eighth of the half-circle. The size of the interior corresponds to the shortened semicircle of the cylindrical blades ( 2 ) in the plan of the disc ( 1 ).

1c illustrates the three-bladed turbine in Aufsicht.

1d shows the outline of a four-bladed turbine. I called this turbine screw turbine. Shown in the lower part of the drawing, the lower disc ( 1 ), in the upper part of the drawing, the upper disc ( 1a ).

From the drawing it can be seen that the inner circle ( 4 ) of the lower disc ( 1 ) significantly larger than the inner circle ( 4 ) of the upper disc ( 1a ).

The screw-type turbine represents a further improvement in terms of synchronism and speed achieved by the fact that the four blades are directed upwards towards the upper closing disc (FIG. 1a ) rejuvenate.

The Screw turbine surpasses in speed the Savonius turbine by about 50 percent.

The construction of this screw turbine is in the supertension of the 1e clarified.

In this turbine, we can from the lower disc ( 1 ), from the beginning of the outer edge ( 9 ) a scoop ( 2 ) to outer edge ( 9 ) of the opposing blade ( 2 ) straight ahead as seen on an imaginary line cross through the center of the turbine in a narrow slit.

Each of the four blades is on the upper disc ( 1a ) offset on the outside by a quarter of the semicircle, so that the outer edge ( 9 ) of the blade ( 2 ) tapered upwardly at the top The inner edge of the blades are again tapered from top to bottom, so that each blade ( 2 ) in the inner circle ( 4 ) is cut at the bottom by a quarter, with the result that at the upper disc ( 1a ) as seen through a crosshair through the center of the turbine through a narrow gap can from the outer edge ( 9 ) of a blade to the outer edge ( 9 ) of the opposed blade.

In the drawing it can be seen that the inner circle ( 4 ) of the lower disc ( 1 ) is significantly larger than the inner circle ( 4 ) of the upper disc ( 1a ).

at the many, each varied models of the turbines I built as compared to the Savonius turbine and as a comparison of mine Turbines among themselves, I researched the properties mentioned in the text.

My previously shown turbines can be combined be with one about it mounted collector room.

The 2 shows a four-bladed turbine, which will be connected to an overlying collector space, in plan view on the plane of the disc ( 1a ).

Under the upper disc ( 1a ) of the turbine is a narrow space through four horizontal plates ( 7a ) separated. This will make four shafts ( 7 ), which have exactly the same shape as in the plan of the 1 shown disc ( 1 ) through the blades ( 2 ) divided rooms ( 6 ), which are located in 1 under the disc ( 1 ) are located. In 2 it is shown that the shafts ( 7 ) below the disc ( 1a ) are located.

2a shows the shafts ( 7 ) in cross-section, cut vertically. It can be seen that the sheets ( 7a ) are mounted obliquely upward and end at the central space ( 4 ), which is closed from the inside, where the propeller ( 11a ) is installed. The shafts ( 7 ) each have an air outlet ( 8th ) to the collector room. The arrows ( 3a ) show the direction of the wind in the shafts tapering towards the center of the turbine ( 7 ). The openings ( 8th ) are provided with flaps, which, when the wind directly on the respective shaft ( 7 ) blows, opens and closes automatically when the wind 7 ) not acted upon.

The 3 shows the four-bladed turbine Collector attachment in Aufsicht.

The wind coming from the entrances ( 8th ) into the collector room, runs in the same direction as the turbine is running, around the chimney ( 10 ) around. The air warms up in the collector room.

The big propeller ( 11 ) located in the lower part of the chimney ( 10 ) is fixed and rotates with, compresses all the air that is in the collector room, upwards. It rises up to the roof of the collector and from the side opening ( 12 ) of the chimney ( 10 ) down again, pulled down by the suction of the fixed propeller ( 11a ) in the room ( 4 ) in the middle of the turbine. The downflowed hot air mixes with the colder air that enters the center of the turbine from the outside. By mixing the hot with the colder air, the air in the central space of the turbine expands and creates an additional greater pressure. At the same time it exerts an additional force on the output nozzles of the turbine, because the warm air in the middle of the turbine mixes with the colder air flowing in from outside and accelerates it. As a result, a fast running of the turbine can be achieved. become.

If the heat in the collector room is too high, the propeller ( 11a ) keep the turbine moving only with the warm air and low wind supply. This would require the propeller ( 11a ) so that it runs freely and only runs in the direction of the turbine. The mixing of the hot air with the colder low wind entering the turbine could allow the turbine to continue running.

The wings of the propeller ( 11a ) are set so that they only pull air from the top down, ie down from the collector room. The chimney ( 10 ) carries the roof ( 13 ) of the collector and the centering ( 14 ) of the turbine towards the outside ( 17 ) in itself. The scaffold serves to secure and stabilize the entire turbine system.

The holder ( 16 ) (Struts) represents the version of the glasses ( 15 The glasses are held by the fasteners, the upstanding curved wings ( 16a ), are screwed to the socket of the glasses and are curved in the wind direction, so that through them the collector on the turbine gets a boost from the wind. They reach from the top, from the roof, to the lower edge of the collector on the disc ( 1a ).

Instead of the full glazing can also partially solar cells used alternately with the glasses become.

The scaffolding ( 17 ) serves to stabilize the turbine system. At the same time it keeps the centering ( 14 ) of the turbine above the roof of the collector.

( 18 ) represents an outer ring that can carry and hold the entire collector. It is an edge frame, which is fastened around on the pipe string inside which the disk ( 1a ) runs without touching the socket.

Claims (10)

Three- or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that the vertical turbine in each case three or four cylinder-shell-shaped blades ( 2 ), which are equidistant from each other with the outer edges on an outer circle on the lower disc ( 1 ) or on the corresponding outer circle of the upper disc ( 1a ), whose inner edges, of which each about one-eighth of the half-shell is cut off, do not start in a small, concentric inner circle ( 4a ) of the discs ( 1 ) and ( 1a ) but on an inner circle ( 4 ) with a larger radius, creating larger openings for the wind flow. Three or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that under the disc ( 1 ) four flat containers ( 6 ) in the form of the blades ( 2 ) and each bounded by the line of the interior ( 4 ), which are half-filled with viscous liquid, such that when the turbine is stationary, the viscous liquid is deposited on the bottom of the containers ( 6 ) distributes the viscous liquid to the outer edges of each container as the turbine starts to run ( 6 ), wherein the liquid must overcome an inclined dam (inclined by about 30 degrees) in each container, and this dam is so high that all the liquid can collect in the outer rim of each container, and in the inner edge of the dam at one point gives a narrow passage in the entire height of the dam, so that in the event that the turbine begins to run slowly or is about to stop, the liquid slowly escapes from this narrow passage back to spread back to the entire bottom of the container. Three or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that in the center of the disc ( 1 ) underneath the disc is the attachment of the shaft ( 5 ) for centering the system and the connection to the electricity generator is located. Three- or four-bladed vertical wind turbines, with or without a collector mounted above, there characterized in that in a special form of the four-bladed vertical turbine, the screw turbine, the four blades up towards the upper final disc ( 1a ) and each of the four blades on the upper disc ( 1a ) on the outside by a quarter of the semicircle opposite the lower disc ( 1 ) is offset, so that the outer edges ( 9 ) of the blades ( 2 ) taper obliquely upward, and that the inner edges of the blades are rejuvenated from top to bottom, so that each blade ( 2 ) in the inner circle ( 4 ) below on disc ( 1 ) is cut by a quarter, such that on the lower disc ( 1 ) from the beginning of the outer edge ( 9 ) a scoop ( 2 ) to outer edge ( 9 ) of the opposing blade ( 2 straight ahead as on an imaginary line cross through the center of the turbine creates a narrow gap and also on the upper disc ( 1a ), as by a thought line cross through the center of the turbine, a narrow gap arises from the outer edge ( 9 ) of a blade to the outer edge ( 9 ) of the opposed blade, wherein the inner circle ( 4 ) of the lower disc ( 1 ) significantly larger than the inner circle ( 4 ) of the upper disc ( 1a ). Three or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that below the upper pane ( 1a ) of the turbine a narrow space through four horizontal plates ( 7a ), whereby four shafts ( 7 ) are formed, which have the same shape as the cylinder-shaped blades ( 2 ) and at the middle room ( 4 ), where the propeller ( 11a ) is installed, wherein the sheets ( 7a ) are mounted obliquely upward, so that the shafts ( 7 ) taper to the center of the turbine, and wherein the shafts ( 7 ) each one air outlet, the openings ( 8th ) to the collector room, which are provided with flaps, which, when the wind directly on the respective shaft ( 7 ) blows, opens and closes automatically when the wind 7 ) not acted upon. Three- or four-bladed vertical wind turbines, with or without attached collector, characterized in that the turbine has a collector attachment, in whose collector space in the middle of the chimney ( 10 ), which is the roof ( 13 ) of the collector and the centering ( 14 ) of the turbine towards the outside ( 17 ), and in the lower part of the large propeller ( 11 ), whereby the wind coming from the entrances ( 8th ) into the collector room, runs in the same direction as the turbine is running, around the chimney ( 10 ), wherein the air heats up in the collector space, which rotates with the turbine and pushes the air upwards, rising to the roof of the collector and to the side opening (FIG. 12 ) of the chimney ( 10 ), from which it descends in the chimney, pulled down by the suction of the fixed propeller ( 11a ) in the room ( 4 ) in the middle of the turbine. Three- or four-bladed vertical wind turbines, with or without a collector attached thereto, characterized in that the outer collector space is formed by fastening parts which hold the support ( 16 ) (Struts), which at the same time the version of the glasses ( 15 ), and the upstanding curved wings ( 16a ), which are screwed to the socket of the glasses and from the top, from the roof, to the lower edge of the collector on the disc ( 1a ), whereby the wings ( 16a ) are curved in the wind direction, such that through them the collector on the turbine gets a boost from the wind. Three- or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that the turbine system is a scaffold ( 17 ), which serves the stabilization of the turbine plant and at the same time the centering ( 14 ) holds the turbine at the top above the roof of the collector, the framework serving to secure and stabilize the entire turbine installation and connected to the pipe string, which has an outer ring ( 18 ), which can carry and hold the entire collector, whereby the disc ( 1a ) is running in this marginal version. Three- or four-petalled Vertical wind turbines, with or without a collector attached above, characterized in that the airtight collector cover instead of the full glazing also partial solar cells alternately with the glasses can be used. Three- or four-bladed vertical wind turbines, with or without a collector mounted above, characterized in that to utilize greater heat in the collector space of the propeller ( 11a ) can be designed so that it runs freely and runs only in the direction of the turbine, including the blades of the propeller ( 11a ) are placed so that they only draw air from the top down, ie down from the collector room.