FLUID TURBINE WITH PARACHUTE-LIKE CATCHERS

Abstract

The device consists of a vertical axis (1), one or more bearing rings (2), rotor (3), one or more pairs of catchers (4) made of light and strong material, flexible connections (5) and valves (6) with air intakes (7). The device can be applied to capture mechanical pressure and extract energy from fluid flows. Since its catchers are made of flexible and light material, it is characterized by a simple structure, light weight, and easy production and repair. Also, the device has a large working area, and reduces to a negligible small value the aerodynamic resistance during the reversible half-turn of the rotor, which further increases its efficiency.

Claims

1-5. (canceled)

6. A fluid turbine having a vertical axis, a rotor and parachute catchers, comprising: (a) a vertical axis 1, located in one or several bearing rings 2, and a rotor 3 in the form of a flat horizontal disk, fixed to the upper end of the axis 1; (b) one or more diametrical pairs of catchers 4 are suspended below the rotor 3, such as the catchers 4 of each pair are centrally symmetrical to each other relative to the axis 1: (c) each catcher 4 is made of flexible material and in the passive position has a half-chamber shape that has an opening on one side; the opening of each catcher 4 has a top edge and a side edge; (d) the upper edge of the opening of each half-chamber is immovably fixed to the rotor 3, and the side edge of the opening of each half-chamber is clamped to the rotor 3 by two or more flexible links 5, the first end of each flexible link 5 being attached to the side edge of the catcher 4 opening, and the second end of each flexible link 5 is attached to the rotor 3; (e) the openings of all catchers 4 are oriented in the same direction of rotation relative to the axis 1either clockwise or counterclockwise; (f) on the upper side of the rotor 3, above the opening of each catcher 4, are located one or more valves 6 with air intakes 7 directed at an angle greater than 45 degrees, relative to the radius of the rotor 3 passing through them; and (g) the valves 6 are in their open position and are directed to the interior of the catchers 4.

7. A fluid turbine according to claim 6, wherein the catchers 4 are located on one level.

8. A fluid turbine according to claim 6, wherein the rotor 3 has a configuration with two or more levels, as in this configuration, the catchers 4 are located one above the other, on two or more levels.

9. A fluid turbine according to claim 6, wherein each rotor 3 level has an odd number of catchers 4.

10. A fluid turbine according to claim 6, wherein the catchers 4 are made of ripstop nylon or polyester.

Description

DESCRIPTION OF FIGURES

[0016] FIG. 1 shows a three-dimensional bottom view of a turbine with four catchers, located on one level.

IMPLEMENTATION EXAMPLES

[0017] FIG. 1 shows one variant of the turbine according to the present invention. The device consists of a vertical axis (1) that passes through two bearing rings (2), and on which a rotor (3) is located in the form of a flat horizontal disk. Four catchers (4) are suspended below the rotor (3), each of them being made of ripstop nylon in the form of a half-chamber, open on one side. The above edge of the opening of each half-chamber is immovably fixed to the rotor (3), and the side edges are clamped to one end of three flexible links (5) whose second end is attached to the rotor (3). All catchers (4) are positioned so that their openings are oriented in the same direction of rotation relative to the axis (1), namely clockwise direction. On the upper side of the rotor (3), above the opening of each catcher (4), there are three valves (6) with air intakes (7) directed under an angle of 75 degrees to the radius of the rotor passing through them. The valves (6) lead to the interior of the catchers (4).

[0018] During its operation, the wind enters the turbine from any direction (the direction it is indicated by arrows in the figure), thereby exerting pressure on all catchers (4). If the rotor (3) is viewed as a clock face and the wind comes from the 6 o'clock direction, the one of the catchers (4) located closest to the 9 o'clock position, captures the pressure in the interior of its half-chamber, causing it to expand and tightens its links (5), from where the pressure is transmitted to the rotor (3) and rotates it around axis (1). At the same time, the wind pressure on all other catchers (4) is lateral or opposite to their openings, and causes them vertically folding to a flat horizontal positiona shape with zero aerodynamic resistance. This vertical folding takes place relative to the areas of attaching the upper edges of the respective catchers (4) to the rotor (3), which are pivot points. In the induced rotation process of the rotor (3), each catcher (4) successively falls to the 9 o'clock position and dissolves under the pressure of side of its opening and under the influence of its weight, then in the 12 o'clock position shrinks under lateral pressure to a flat shape and remains in that position until moving to the 6 o'clock position. At the same time, under the influence of the affected pressure of the wind, in the 12 o'clock position, the catcher (4) is moved to the periphery of the rotor (3), in position 3 o'clock turns to leeward and covers its links (5), and in 6 o'clock position is moved to axis (1). Also, when approaching position 6 o'clock the air intakes (7) begin to capture the wind before the corresponding catcher (4), still compressed, and feed it through their valves (6), thus accelerating the initial expansion of the catcher opening (4), and begin to inflate it immediately after moving to the 6 o'clock position. Then the wind instantly gets direct access to the interior of the catcher (4), and causes its full dissolution, giving an additional rotary motion to the rotor (3), during the entire transition between the 6 o'clock and 12 o'clock positions. When approaching a position 12 o'clock due to its position, the air intakes (7) stop supplying air to the corresponding catcher (4) before stopping the wind pressure through the opening of the same catcher (4), and remain in this state until approaching the 6 o'clock position. Through all the time the rotor (3) exerts constant aerodynamic drag, balanced relative to axis (1), whose value is negligibly small. The process continues until the wind stops.

Application of the Invention

[0019] The device can be applied to capture the mechanical pressure and extract the energy from fluid flows. Because its catchers are made of flexible and light material, it is characterized by a simple structure, light weight, and easy production and repair. Also, the device has a large working area, and reduces to a negligibly small value the aerodynamic resistance in the reversible half revolution of the rotor, which further increases its efficiency.

LIST OF DESIGNATIONS

[0020] 1 Vertical axis [0021] 2 Bearing rings [0022] 3 Rotor [0023] 4 Catchers [0024] 5 Flexible connections [0025] 6 Valves [0026] 7 Air intakes