CZ2005142A3 - Windmill rotor comprising multiple separate wind channels - Google Patents

Abstract

MPROT13 polypeptides and polynucleotides and methods for producing such polypeptides by recombinant techniques are disclosed. Also disclosed are methods for utilizing MPROT13 polypeptides and polynucleotides in therapy, and diagnostic assays for such.

Description

CIRCULAR Honeycomb Rotor

Technical field

The invention relates to an ideal circular honeycomb rotor with curved tubular trapezoids for wind generators and most propeller wheels. Its aim is to increase the performance of wind generators and propeller wheels, which is achieved by completely closing all boundaries of the surfaces inserted into and through the coaxially arranged tubular cylinders passing through the curved pieces by resting them against these tubular cylinders. All components are assembled into a circular honeycomb structure consisting of modules of circularly curved tubular trapezoids which, when receiving all wind forces, multiply by the order of twice the number of trapezoids, simultaneously multiplying the contact surfaces with the wind more than twenty times. Rotors of wind generators generate most of the wind forces by multiplying the number of trapezes and by multiplying their contact surfaces with the wind. The same goes for the rotors of most propeller wheels: multiplying the number of trapezoids, complemented by multiplying their contact surfaces with the wind, leads to a multiplication and optimal use of the driving centrifugal forces acting.

BACKGROUND OF THE INVENTION

The state of the art envisages using rotors for wind generators with a variety of applications and various dimensional dimensions. The rotor generally consists of a hub usually with three blades mounted therein; some models are equipped with directionally adjustable blades, capable of easily adapting to the wind direction. The outer boundaries of the surfaces of the wind generators currently in use and most of the propeller wheels are free, unrestricted, which means that most of the driving centrifugal forces escape through the propeller wheels and remain unused. Commonly used wind generators having three blades with a very small contact surface usually achieve relatively low performance in terms of wind speed.

SUMMARY OF THE INVENTION

Circular honeycomb rotors with circular curved tubular trapezoids are ideal for wind generators and most propeller wheels. They consist of several coaxially arranged tubular cylinders with interposed curved pieces forming circularly curved tubular trapezoids, the basic purpose of which is to maximize wind power performance. This maximization of wind power performance in wind generators and propeller wheels is, on the one hand, possible by replacing commonly used blades with curved tubular trapezoids that have the ability to multiply wind contact surfaces more than twenty times. In addition, the propeller wheels also maximize most of the centrifugal forces driven by the rotation of the engine and passing to the blades. On the other hand, the trapezoids are embedded in coaxially arranged tubular cylinders, thereby closing all the boundaries of the trapezoidal surfaces and, as a result, the rotor of the circular honeycomb structure. In wind generators, an open funnel with an outwardly oriented conical opening is attached to the largest diameter tubular cylinder to increase the surface at the wind inlet for the rotor. The curved tubular trapezoids in commonly used wind generators have a gradual inlet that gradually decreases towards the outlet, creating little pressure. This is natural in this type of wind rotor because the wind inlet and outlet areas are oriented in the same direction. However, in the solution of the present invention, the gradually increasing curvature of the curved tubular trapezoids will cause the wind flow to be diverted to another direction, thereby automatically reducing the wind power at the outlet, as it does in wind turbines. The characteristics of the wind rotors for the propeller wheels will generally be substantially the same, but increased by the effect of centrifugal forces. In the case of regular wind exit regions of circularly curved tubular trapezoids, these will have to be fixed or calculated in advance to obtain adequate pressure. In the case of adjustable wind exit areas, this will be automatic.

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The aforementioned circularly curved tubular trapezoids are assembled in a plurality of coaxially arranged tubular cylinders by inserting the individual curved pieces into each of said cylinders to form a complete structure in the form of a circular honeycomb structure with circular curved tubular trapezoids inside. The curved tubular trapezoids for wind generators and propeller wheels may have any of the prior art geometrical shapes, for example, circular, oval or polygonal, with as many regular or irregular side walls as necessary. Such trapezoids may include trapezoids of similar shape, for example, angular trapezoids, or any irregular shape whose sole function would be to minimize wind force. A cone-shaped funnel with an inward opening is attached to the tubular cylinder of the larger diameter propeller rotor, which reduces the wind exit surface and consequently minimizes the wind force at the wind exit.

In most propeller wheels, the curved tubular trapezoids have less wind inlet surfaces than wind exit surfaces to increase air pressure. In this way, most of the centrifugal and driving forces originating from the motor will be generated according to the present invention. The same is true for wind generators, but in this case, the curved trapezoids will have wind inlet surfaces larger than wind outlet surfaces to reduce air pressure, which, combined with the large rotor surface, will generate a significant amount of energy generating most wind power .

The circular honeycomb rotors for wind generators and most propeller wheels will have a large number of circularly curved tubular trapezoids with a surface that is more than 20 times the surface of conventional rotors. Large contact surfaces with wind multiply its efficiency by completely closing all external boundaries of the wind rotor surfaces.

The advantage of circular honeycomb rotors for wind generators and most propeller wheels with circularly curved tubular trapezoids is the multiplication of the number of trapezoids and therefore the multiplication of the contact surface with the wind or the friction of the wind on the curved pieces, resulting in maximizing force wind to rotor, which in most cases will also be multiplied. Since the boundaries of the trapezoidal surfaces are completely closed by means of coaxially arranged tubular cylinders, it is optional whether each row is aligned or not. This is the essence of the present invention.

Circular honeycomb rotors for wind generators and most propeller wheels will be able to move in both directions, depending on the location of the curved pieces in the circularly curved tubular trapezoids.

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BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be explained in more detail by way of a detailed description of examples of specific embodiments thereof in connection with the accompanying drawings, in which:

Giant. 1 is a front view of a circular honeycomb rotor for wind generators from which a coaxial arrangement of a plurality of tubular cylinders 1 can be seen (four tubular cylinders are shown in the figure). In order to maximize the surface at the wind inlet, a cone-shaped funnel 4 is attached to the largest diameter tubular cylinder, which is open outwardly. In each of these tubular cylinders there are bent pieces 2 (twelve, ten, eight, and six curved trapezoids in each of the coaxially arranged cylinders starting from the cylinder having the largest diameter and advancing from one diameter to the other). This arrangement explains a circular honeycomb structure made up of individual circularly curved tubular trapezoids 5. Finally, a head or hub 3 arranged in the center can be seen to be placed on the alternator axis.

Giant. 2 is a front view of a circular honeycomb rotor for most propeller wheels, from which the coaxial arrangement of several tubular cylinders 6 (four cylinders are shown) is visible. To the tubular cylinder with the largest • · ·· ····

The diameter is a cone-shaped funnel 9 with an inward opening to minimize the surface area at the wind outlet. In each of these coaxially arranged cylinders there are embedded curved pieces 7 (twelve, ten, eight, and six curved pieces in each of the coaxially arranged cylinders starting from the largest diameter cylinder and progressing from one diameter to the other are shown). This arrangement explains the circular honeycomb structure made up of the individual circularly curved tubular trapezoids 10. Finally, a head or hub 8 arranged in the center can be seen to be mounted on the axis of the alternator.

Giant. 3 is a cross-sectional view of the rotor of FIG. 1, from which the coaxial arrangement of a plurality of tubular cylinders I with a hub or hub 3 and the width proportions of the curved pieces 2 relative to each other can be seen. Further, it can be seen how the cone-shaped funnel 4 is mounted on the largest-diameter tubular cylinder and opens outwardly. In addition, arrows indicating the wind direction are indicated in the circularly curved tubular trapezoids 5.

Giant. 4 is a cross-sectional view of the rotor of FIG. 2, from which the arrangement of several coaxially arranged tubular cylinders 6 with a centered hub or hub 8 and the relative width proportions of the bent pieces 7 can be seen. a cone-shaped funnel 9 with an inward opening to minimize the surface area at the wind outlet. In addition, arrows indicating the wind direction are indicated in the circularly curved tubular trapezoids 10.

Giant. 5 is a cross-sectional view of one half of the tubular cylinder of the largest diameter wind generator from which it may be seen to bend the individual pieces embedded in each of the circularly curved tubular trapezoids. In addition, the surface reduction at the wind outlet in the wind generators, the direction of wind entering the rotor indicated by the arrow V, and the direction of rotation of the rotor indicated by the arrow, may be noticeable.

R.

Giant. 6 is a cross-sectional view of one half of the tubular cylinder of most of the largest diameter propeller wheels from which it may be seen to bend the individual pieces embedded in each of the circularly curved tubular trapezoids. In addition, the reduction of the wind inlet surface relative to the larger wind outlet surface, the direction of wind entering the rotor indicated by arrow C, and the direction of rotation of the rotor indicated by arrow H, can be seen.

DETAILED DESCRIPTION OF THE INVENTION

A circular honeycomb rotor for wind generators and most propeller wheels with four or more circularly curved tubular trapezoids consists of a hub 3, 8 located in the center of the rotor; two or more coaxially assembled tubular cylinders 1, 6 with curved pieces 2, 7 interposed therebetween and forming circularly curved tubular trapezoids. In the rotors for the wind generators, the largest diameter tubular cylinder 1 will be provided with a cone-shaped funnel 4, which is arranged at the rotor inlet and has an outward opening. In propeller rotor rotors, the largest diameter tubular cylinder 6 will be provided with a cone-shaped funnel 9 which is arranged at the rotor outlet and has an inward opening. All of the individual components may be assembled together by means of conventional methods such as welding, riveting or screwing. In the case of rotors for wind generators, the dimensional dimensions may vary according to the desired performance, having diameters similar to those of conventional wind generators. The construction materials used must be light, metallic and corrosion resistant. As for the construction materials for the rotors of most propeller wheels, cast iron or light and high-strength alloys as well as sheathed plastics are recommended.

The circularly curved tubular trapezoids 2 are installed in the wind generators to minimize wind output. This is achieved by larger wind inlet surfaces and smaller wind outlet surfaces, as indicated by the direction of arrow V in Fig. 5. The smaller wind outlet surface results in low pressure, the existence of which is very important with respect to the large rotor surface.

In circular honeycomb rotors for propellers, the pieces and the circularly curved tubular trapezoids 7 will have smaller surfaces at the wind inlet and larger surfaces at the wind outlet, as indicated by the direction of arrow C in Fig. 6.

The head or hub 3, 8 will be adapted to be mounted on the axis of the alternator or engine according to their attachment parameters.

Based on the fact that the object of the present invention has been presented above and described clearly and to a sufficient extent in terms of its use, I declare that it is new and that it is my own invention. Minor details, such as shape, dimensional dimensions, materials and constructional procedures, may be varied as necessary, in accordance with what has been presented and described in the present description, provided that these changes do not extend beyond the particular features of the claimed subject matter summarized and set forth in the appended claims. .

Claims (3)

PATENT CLAIMS A circular honeycomb rotor with curved tubular trapezoids for wind generators and propeller wheels, comprising a set of pieces (2,7) surrounded by tubular cylinders (1, 6) having a hub or alternator hub (3, 8) at their center; or motor, replacing conventional blades, characterized in that the boundaries of the surfaces of all pieces (2, 7) having a circularly curved tubular trapezoidal shape are closed circumferentially with coaxially arranged and module-assembled tubular cylinders (1, 6), and positioning the trapezoidal pieces between individual coaxially arranged tubular cylinders may coincide or alternate with each other to form mutually coupled bent trapezoid-shaped tubes (5, 10), and the complete structure has a circular honeycomb structure centered by the hub or hub (3, 8) for the alternator or motor , and each of the tubes The metal rollers (1, 6) have four or more pieces (2, 7), the rollers being assembled into one or more pairs, and all trapezoidal pieces (2, 7) are bent to provide a greater contact surface with the wind and thereby to maximize wind power, and the circular panel of bent tubular trapezoids may have any regular or irregular geometric shape. Circular honeycomb rotor with curved tubular trapezoids for wind generators, according to claim 1, characterized in that it has pieces (2) with circular curved tubes (5) forming a trapezoidal shape and interconnected by coaxial rollers (1) and surfaces at the wind inlet are larger than the wind exit surfaces due to the progressive curvature of the trapezoids (2) deflecting the wind current to another direction, and all reduced wind exit surfaces in these trapezes (2) create little pressure, and a tubular cylinder (1) with larger diameter at its inlet is provided with a funnel (4) of circular conical shape with an outward opening. A circular honeycomb rotor with curved tubular trapezoids for most of the propeller wheels according to the preceding claims, characterized in that it has trapezoids (7) forming with coaxially arranged cylinders (6) curved trapezoidal tubes (10) providing a complete structure of a circular honeycomb structure, and circular curved tubular trapezoids (7) have smaller wind inlet and larger wind exit surfaces, and by fully enclosing the boundary of the surfaces, the performance of most centrifugal forces is optimized; the tubular cylinder (6) with a larger diameter has a funnel (9) with a tubular conical shape attached to its outlet which reduces the surfaces at the wind outlet.