OA17999A - Paddle-wheeled wind turbine. - Google Patents

Abstract

Device of a machine operating by the force of the wind. The invention relates to a device for producing work from the movement of wind such as electricity if it is connected to a dynamo, it is remarkable for its direction of rotation of the rotor in the direction of the wind. It is made up of four blades (1) (1 ') (1 ") and (1"') and their orienters (1d). Place around the middle of a rotor (2) the blades (1) (1 ') (1 ") and (1"') are linked two by two by two axis-blades (1E) and (1E ') which are intersect in + in the latter. This assembly is supported by a fork (3) replacing the nacelle and the ram in known wind vector machines and the whole rest on a fixed base (4). When the vane (1) at the top is facing the wind, the others are sideways and the one behind the rotor (2) the (1 ') serves as rudder by sudden change of direction of the wind during the rotation of the rotor (2) The arrangement according to the invention is particularly intended for the production of electricity by the wind if it is coupled to a dynamo by belt through its pulley (2k) or directly on its main shaft (2p). Fig. 1

Description

The invention relates to a wind turbine with blades and a rotation system in the direction of the wind.

The object of the invention relates in particular to the technical sector of machines moving by the force of the wind in general and more particularly to wind turbines and all similar machines with a wind rotation vector. Wind turbines known until then, especially the most modern ones, consist mainly on the one hand, by fiberglass blades, which are nested at equal distances around a rotor by a ball head which, allowing the blade to make an orientation movement. These two pale and rotor components continue through a main shaft in the nacelle on a ball bearing to get connected to a speed multiplier linked to a generator. A directional brake is linked to the main shaft from the bottom of the latter. All this pale rotor and nacelle system are held and supported by a pestle made of steel cylinders.

These pestles can wait 40 to 80 meters in height if not more and 8 to 30 meters underground, they weigh about 100 tons, their rotor nacelle and blades are 60 tons, their blades need powerful wind force to move the rotor, c This is why currently we tend to resort to short wind turbines placed in seas in order to acquire powerful wind force. These wind turbines are difficult to operate on dry land and their manufacturing and installation costs are very low, their operating system based on the only kinetic force generated by the rotation of its enormous mass of the blades which need a consequent force of wind to be tilted through the direction of the wind like all the wind turbines known until then, which turn on a deflection of the wind from the wind causing resistance to the force received, and therefore loss of force acting on all the blades.

The steerable vane wind turbine according to the invention overcomes these problems and underperformance and will explain its advantages in more detail. This wind turbine has only one component as a nacelle and rams in the shape of an inverted bicycle fork allowing the rotor 2 to be across the direction of the wind and the vane 1 from above on the rotor facing by its surface to the wind and causing the mobile rotation system to oppose no resistance to the acting force of the wind unlike those known.

These characteristics, systems and others will emerge from the following description

To establish the subject of the invention, without however limiting it in the accompanying drawings.

Figures 1 is a front view of the invention showing all of the external organs which are illustrated by way of example.

Figure 2 is a side view of the invention with its principle of operation.

FIGS. 3 is a general horizontal sectional view of the rotor and certain of the fork support elements.

Figure 4 is a representation of the box (section)

Figure 5 shows the front of the rotor (the box) in section.

FIG. 6 is a sectional view of the belt showing a vane with its vane axis.

Figure 7 is a sectional view of the entire rear of the rotor (can closer)

Figure 8 is a section through the entire upper right arm.

Figure 9 shows the pulley block in section.

Figure 10 a sectional view of the part of the lock mounted on the base The object of the invention is made more concrete by describing it without limitation in the embodiments illustrated in Figures 1 and the general aspect of the invention is shows in front and side allowing a good understanding and to apprehend all the parts and components assembled in order to have a precise and clear idea on the whole of this machine the other illustrations in semi detail and detail of the elements, sometimes in section.

The invention in itself is made of three kinds of semi-movable members, constituting the blade 1 and the fork 3, a movable member, the rotor 25 2 and a fixed member, the base 4 figures let 2, and two essential parts the rotor 2 forming the motor part, tan disc the fork and the base 4 forming the support. Part 1 of the motor has the appearance of a water wheel, but with alternating motion vanes on the impeller which is the rotor here, the two components are not fixed to each other unlike the impeller. hydraulic. Its rotor has the appearance of a bicycle hub with two ball bearings (2 E) and (20) on each side, with an axis (2p) Figure 3 which is the main shaft, its rotation is between the two parts of the fork (3) figure 1 and all of these three components are placed on the base 35 4 figure 1-2 the blade 1 in figure (1) and (2) represent the first component of its element motor which is mainly made up of two plates glued to each other with orienters. It has a hammerhead shape with a wide rear and a narrow front which is the top. The backplate (la) for the prototype and can also be hard nylon plate and (lb) is hard cardboard covered with protective paint. These two glued plates form the vane 1 which by orientator (ld) make it possible to balance and orient the four blades facing the wind for the one located at the top of the rotor 2 (pl) and the windward sides for the three others which are in positions (p2) and (p4) figure 2 the orientators (la) are made of screw head bolts and hard nylon yoke figures (1-2), they are of different dimensions and therefore of weight different and also of different number per blade 2-2 for 1 and 4, and 1-1 for 2 and 3. Without being limited to the sole description of vane 1 and its orienters (ld), a detail of the positions and dimensions of these is necessary during the operation of this wind turbine.

Dawn 1 position 1 figure 2

Has 1 bolt of 60 / 5mm in the center of the vane and 1 bolt of

60 / 5mm at the reduced end of the vane.

The dawn 2 positions 2 figure 2

Has 1 15 / 3mm bolt at the end of the reduced blade tip.

The dawn 3 positions 3 figure 2

Has 1 60 / 5mm bolt on the bottom center of the reduced tip of the vane

The dawn 4 positions 4 figure 2

Has 1 20 / 5mm bolt on the reduced end of the vane and 1 20 / 5mm bolt on the lower center of the reduced end of the vane.

The vanes (l-l'-Γ'-Γ ”) act on rotor 2 through the two axes (1E) and (1E ') which cross + in rotor 2 figures 1 and 3, under the force of the wind transmitted over them. The blade axles consist of a 25 6 iron (1H) of two plates (lf) and (lf ’) Figures 3 and 6 each comprising two fixing holes (IG) and (IG’). These two axes (1H) and (1H ') by their circumferential parts around the axis iron (1H) are posed and moved alternately on a belt (2H) in bracelet around the rotor body 2 figure 2 and 3 these two axes -blades (1E) and (1E ') are fixed by their plates (1F) and (IF') through two fixing holes (IG) and (IG ') to the blades in pairs which face against sides in FIG. 1, and 6. The components of the motor part of this wind turbine is made of 90% hard nylon molding assembly on series to size, the pins and bolts or screws are naturally made of iron only the support 35 wedge-blade (2 d) is in bronze. Figure 1-2 and 3 rotor 2 of an elongated cylindrical shape finished with an axis which is its main arabic (2p) figure 3 and 7 having a threaded end (2r) and its nut (2v) figure 1-2 and 3 allows to clamp the pulley block system (2u) so that it is integral with the main shaft (2p).

Because the pulley block (2u) carries within it the pulley (2k) figures 1 and 3 and held by the shim pulley (2q) figures 3 and 7.

The rotor 2 itself is composed of two essential parts, on the one hand the box (2a) which carries within it a stabilizer (2w) figure 3 which is a round iron of 6 in the prototype, transverse to its interior in parallel to the vane axis (1E ') along these sides four lateral faults, the vane axis couloirs (2M) (2M') (2M ”) and (2M '”) figures 4 and 5 and four holes d 'blade axis (2N) and (2N') (2N ”) and (2N '”) as well as two belt wedges (2ΕΓ) and (2H ”) allowing the belt seal of (2H) figures 3 and 4 to be clamped. on its external part of the dies (2T) four so-called locking holes (2s) (2s') (2s ”) and (2s'”) thus allowing the four fixing bolts (2L) (2L ') (2L ”) and (2L '”) figure 3 to block the two parts of the rotor 2 after screwing on the dies (2T) and (2T) figure 3-4 and 7 of the box (2a) to the firm box (2i) by wedging on the wedges - belts (2H ') and (2H ”) the joint belt (2H) with its poses (2Z) (2Z') (2Z”) and (2Z '”) figures 3,4 and 5.1a belt (2H) to the same number of blade axis passage faults (2Y) (2Y ') (2Y ”) and (2Y'”) and of axis holes (x) (x ') (x ”) and (x' ”) It is on this joint belt (2H) with its poses (2Z) and (2Z ') (2Z”) and (2Z' ”) figures 1-2 and 6 that are posed and changed by its four circumferential parts (II) (1Γ) (II ”) and (1Γ”) of the two blade axes.

The rotor 2 on the face of its box (2a) two fixing holes (2G) and (2G '”) and in the middle the hole of the bearing holder (2b) figure 5 it is by the screws (2d') and ( 2d ”) at its periphery starting from the blade shims (2f) (2f) (2f”) and (2f '”) when to the bearing holder (2b) it is fixed in a hole (2b) figure 5 by the bolt (2c) on the center of the face of the box (2a) where the ball bearing (2E) is housed and on the other hand the box closer (2i) screwed through its dies (2t ') to that of the box ( 2t) figure 5 3 4 and 7 and blocked by the four bolts (2L) (2L ') (2L ”) and (2L'”) figure 3 The fork 3 constitutes the first support element of the wind turbine with orientable blades it comprises 3 essential parts. A cross bar (3a) supporting the two sleeves vertically on both ends, the left arm and the (3G) that of the right arm Figure 9, each of them are made up of elements.

The lock (3a) is made of two square tubes and a round tube all in aluminum Figure 10 carries the axle hole (3a ’), the right bolt hole (3a”), all vertical to the lock. It is held together with the round tube (3c) by the bolt (3c ”) which is integral with the second square tube (3b) by a fixing bolt (3b”) through the retaining hole (3b '), the ( 3b) carries on him the first support arm (3E) carrying the fixing hole (3E '”) of the forearm (3G) the second square tube (3b) carries in. its side a side hole (3F ’”) of the holding iron it ends with a nylon tail (3d) carrying the hole (3d ’) of the forearm support of the bolt (3d”) Figures 1 and 10.

The right sleeve of the fork 3 is also made up of elements, the forearm (3G) is placed on the right part of the lock (3b) and (3d) its end is fixed on a U (3E) in hard nylon and the back on a retaining bolt (3d ') figure the vertical part is fixed from above to a hard nylon joint (3i) which is clamped by the two parts of a ring (3H) figure

These two parts clamp the bottom of the joint (3j) on the top of the forearm (3G) by a nut (3F '”) on the threaded end (3F') of the holding iron (3F) The top of the joint ( 3j) carries the hole (3i ') of the elbow iron (3R) and the support iron (3N) in its front hole (3j') figure 1 the elbow iron (3R) is the spine, it allows to bind the forearm (3G) through the joint (3j) and infancy in the latter by its end (3R ') figures 1 and 8 by its upper horizontal part in the flow (3K) through its channel (3K) while passing by the wrist (3L) which carries through its bottom hole the (3L ”) of the front of the support iron (3N) and all tightened by the nut (3M). The handle (3L ”) by its upper part carries the column (3L '”) and the hollow axis (30) of the central bearing figure 8 this hollow axis (3o) carries the main shaft passageway (3o ”) and the die (3o ') which is clamped on the column (3Γ ”) through its hole (3L') and the large capo (3M) which carries the hole (3M ') for the passage of the hollow shaft and the passage of the column (3L '”) through the fault (3p') of the large capo (3p) and the small capo (3U) all tightened together by the hollow nut (3q) through the dies (3q ') figures 3 and 8.

When in the second sleeve there is the left arm (3T) a square aluminum tube slightly curved on both ends, it is linked to the round tube (3c) of the lock by a bolt (3c ') through a joint (3c ” ) by a hard nylon nut without internal die through the hole (3T ”) of the arm (3T) to fix it inside the round tube (3c) figure 1 and 101st arm (3T) in square tube is held by the holding iron (3R) which forms an angle at its middle and its two die ends (3R ') and (R ”) which are fixed in holes on the square tube (3a) of the lock through the hole (3R' ”) And the other end (3R” ”) in the sleeve of the arm (3T) through the hole (3T ') at its top, by the spindle iron (3U) figure l of the left ball bearing of the rotor 2 from and by the iron nut (3U ') and (3U ”) in hard nylon, its long end after the nut that carries the ball bearing axle head (3U”) and the capo (3W) of left bearing protection (3G) figures 1 and 3.

The base 4 is the fourth and the last component of the invention, it is this which supports all the other components, it is fixed. The crown (4a) is the main element, and has an iron wheel placed on its side, inside it is fixed the axle holder (4B) forming almost integral with the axle (4c) carrying the nut figure 10 on the part of the axle carrier (4b) is a flat iron carrying the axle passage troop (4d) wedged on it where the bearing (4E) is placed and on the latter is also placed the joint ring (4E ') in iron and the everything is covered by the small hard nylon capo (4 G).

According to the invention, Figures 1 and 2 show the general aspects of the wind turbine with steerable blades and facilitate understanding. Its system of operation in figure 2 presents the four blades

1-1'-1 ”-Γ” which are stabilized in the operating position P thanks to the stabilizer (2w) in figure 3. This 6 round iron bar in the prototype crosses the box (2a) by the width, vane 1 which is in position (p 1) at the top of rotor 2 in FIG. 2 which is facing the wind. The path of the wind is indicated by the arrow (F) pointing at the dawn of? high (1). The acting force of the wind is on the total surface of the blade 1 which causes the latter to tilt backwards in the direction of the wind, tan disc the blade (1 ”) which is on its opposite side to the wind as well as the (1 'and Γ ”), only (1) figure 2 which undergoes the force acting on it. The positions of these vanes facing and side are ensured by orienters thanks to their weights and positions on the vanes, the vane axles which believe in + in the rotor 2 by dragging the latter with them on the left (2E) and right bearings (2o) figure 3 the acting force of the wind is transmitted on the blade 1 to the rotor 2 by the blade axis (1E) thus driving the body-pulley system (2u) on its bearing (2t) the entire rotor 2 which began to rotate between the two arms (3G and 3T) of the fork (3) at the speed and force of the wind received 1 in 1 on the surfaces of the blades by the one in position facing against the direction of the wind which is in position (Pl) from above rotor 2 and under the effect of the orienters (ld) of the vanes (Γ and 1 ”) which are in position (p2) and (p4) side by side facing the wind in horizontal ascends to the opposite of the rear one (p2) by the side in the direction of the wind in vertical and from below (p3) the front side face in vertical thus starting to mount it for the position (p4).

Each time the blades of the same axis reach position (p2), orienters (ld) tilt the blades in position (p4 and p2) from the front (p4) and from behind the rotor 2 (p2) in turning, and the same possessed begins again each time a vane from down (p3) in ascending when the long side of the vane reaches the level (p4) that is to say facing the wind. The force acting on the blade in position (pl) causes a kinetic movement to transmit with it the pulley (2k) held on the axis (2p) by the block pulley shims (2q) in the block faults (2q) of the block pulley (2u) figure 3 the blade 1 '”held at level (p4) by the blade shim (2F”) figure 2 and the blade 1 in position facing the direction of the wind, so the same process begins again with the wide sides of the following vanes, and during rotation the vanes in position (pl) and (p4) are wedged on the wedges (2F ') and (2F ”) in their positions and the other two (p2) and (p3) are free with their blade shims (2F) and (2F '”) And faced with a sudden change in wind direction, the blade which is in position (P2) behind rotor 2 provides the directional guide like a rudder, pushed by the wind on one of the two sides by pivoting the fork 3 on itself through the rotor 2 by the axes of its bearings (3U) figure this is how the wind turbine with orientable blades works.

We underline the interest and the advantages of this invention which is a wind turbine rotating in the direction of the wind with blades which are oriented towards and against the wind by its very high performance due to the very large surface of its blades and which does not oppose resistance to the acting force unlike those known until then. By its low cost due to the materials used and its lightness which facilitates manufacture, transport, installation and its power. By way of non-limiting example, the 500/1 type of the dimensions of the lF®i drawing t 560 horsepower without counting the kinetic force generated by the weight of the blades and their orienters.

The device according to the invention is particularly intended for the production of electricity by the wind if it is coupled to a dynamo.

Claims (5)

Claim Device of a wind turbine with rotation of the rotor (2) in the direction of the wind with eastern blades (1) in that the fork (3) supporting its two components on a base (4) and all the elements and parts which are in description and its operating principle. 2- ₁ Device according to claim 1, characterized in that the blades (1) which is the first component motor and all the elements which compose it to mention in the description and the drawing allowing to tilt the rotor (2) under the wind action. 3 „Device according to claim 1 characterized in that the rotor (2) which is the second engine component supporting the vanes (1-1 1 Γ”) and carrying the three bearings described and all the other elements that make it up mentioned in the description and drawings allowing it to be turned under the action of the wind. Device according to Claim 1, characterized in that the fork (3) which constitutes the support for the rotor (2) and the others (1-Γ-1 ”-1” ') as well as all the elements which compose it described in the description and the drawings also allowing under the action of the wind on the blade in position 2 last the rotor (2) to make it turn facing the direction of the wind. 5 * Device according to claim 1 characterized in that the base (4) which is the base for maintaining all the components of the machine and its elements which compose it mentioned in the description and the drawings. Abstract Device of a machine operating by the force of the wind. The invention relates to a device for producing work from the movement of wind such as electricity if it is connected to a dynamo, it is remarkable for its direction of rotation of the rotor in the direction of the wind It consists of four vanes (1) (1 ’) (1”) and (1 ”’) and their orienters (ld). place around the middle of a rotor (2) the blades (1) (1 ') (1 ”) and (Γ”) are linked in pairs by two blade axes (1E) and (1E') which cross in + in the latter. This assembly is supported by a fork (3) replacing the nacelle and the ram in known wind vector machines and the whole rest on a fixed base (4). When the vane (1) at the top is facing the wind, the others are sideways and the one behind the rotor (2) the (Γ) serves as a rudder by sudden change of direction of the wind during the rotation of the rotor (2) The arrangement according to the invention is particularly intended for the production of electricity by the wind if it is coupled to a dynamo by belt through its pulley (2k) or directly on its main shaft (2p)