NL1035478C2 - Water wheel for hydro power plant, has flat hydrofoil blades diagonally placed in relation to central axis, and vane provided at angle working against water flow, where camber is added to blades to change angle of blades relative to water - Google Patents

Abstract

The wheel has flat hydrofoil blades diagonally placed in relation to a central axis, and a vane provided at an angle working against water flow, so that the wheel is brought in motion by flow of water under pressure through the blades. A camber is added to the blades to change the angle of the blades relative to the water, where the rotation state of the blades is changed as a result of increased pressure of water to deflect the tail of the blades against the force of a spring mechanism.

Description

Water wheel with self-adjusting diagonal blades

A flow-through type of water wheel that is fully functional under water has been described in historical designs and (published) patents.

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Such designs may, for example, consist of a rotor with straight blades, a rotor with hollow blades (Savonius type), or an open (Darrieus type) rotor, provided with wing-shaped (hydrofoil) blades, placed at the same distance around the same axis, parallel to these ash.

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Since the same physical laws apply to flow-through type water wheels as to wind turbines, these designs intended for capturing kinetic energy from air are usually adapted without much modification and found suitable for running water as a driving medium.

It must be borne in mind that the much lower water speed (relative to wind speeds) and much higher density of the medium entails mechanical disadvantages for rotors, such as stagnation at too low water speeds and a hesitant start-up.

For example, both types of rotors (Savonius / Darrieus) are sometimes combined as a water wheel to set up a rotor.

Propeller-type rotors are little efficient (max 20%) under water at such low speeds and, moreover, are "visually unfriendly" because they can hit 25 passing living organisms laterally.

When the water flow is given a deflecting direction along stream-narrowing diffusers (as happens in a venturi), this appears to generate an accelerating flow.

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These diffiisors may consist of curved plates, hydrofoils or round shapes (whether or not forming part of hollow pontoons or caissons), or other suitable surfaces.

Together they can form a closed whole or be arranged in such a way that they leave openings (e.g. slots) free.

Water speed (as it touches the wheel, up to the third power), perpendicular view in m2 and efficiency of the design are important variable elements in the formula that describes the expected axle torque ('torque') of such a wheel (see below) , which is usually intended to be connected to a generator.

The use of wing-shaped blades (with 'hydrofoil' profile according to NACA coding, eg the symmetrical NACA 0020) that are placed at equal distance or in rows perpendicular to a central axis in helical form ("helix") is a feature of many existing designs.

A version of a Darrieus rotor model with straight blades is easier to build and can prove just as efficient.

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Upright blades, as provided in the original Darrieus design, have the disadvantage of making the vibrations generated by their stroke ("pitch") resonate in the construction. This shortens the service life of the components of the construction and uses the energy taken from water flow in part in a destructive sense, which does not contribute to an increase in the shaft torque.

When in the perpendicular view (in flow direction) the blades are placed diagonally, for example so that in this projection they overlap each other - vane by vane -, and thus offer a completely closed view as much as possible in each position of the 'drum', Such vibrations are avoided and this improves the efficiency and the service life.

It is also known that the position of the blades relative to the central axis (and thereby to the water flowing past) per blade can be optimally adjusted for each available flow speed.

The ideal position of blades in a starting rotor is different from a rotor moving at some speed, the camber (the angle with respect to the central axis - in the flow direction) should be greater at start.

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Straight blades in diagonal position also make this possible in practice if they are each provided with their own axis rotation point.

For example, the rotor will start earlier with outwardly expanded blades but will rotate at a higher speed with more blades placed in a parallel position (smaller camber) on the central axis if the drive takes place at a higher water speed.

The possibility of rotation per blade present on one's own individual axis can be utilized by making use of hydropower (since there is a direct relationship between paddle position and hydropower).

For example, the blades can be held or brought into position by a deflecting part of the sharp rear of the hydrofoil blade, against the force of a spring structure (eg rubber profile), or by means of a weight knocked out by centrifugal force (per blade) that on the basis of the rotational speed the blade rotates inwards or outwards against the force of a spring construction (eg rubber profile) and thereby adjusts itself to the flow velocity of the water in order to always take the most ideal position.

The same function could be performed by the presence of 30 expandable / retractable profile parts ("slats") at the front of a 4 wing profile, with an air gap relative to the fixed part of the wing profile. In that case there is a fixed wing part with retractable and expandable front edge which offers more underpressure and therefore more lift in expanded position.

This wing construction is known from aviation.

If the front side of a hydrofoil profile can move relative to the center and rear part, for example on a fixed shaft or sliding slot, it can be closed by a spring kept open by increasing water pressure.

At low water pressure (for example when the rotor is stationary) the expanded slot serves as an extension of the wing profile.

A simple spring mechanism (e.g. consisting of a rubber profile or steel spring) then pushes the moving front of the profile out again when the water pressure decreases. This way the water pressure regulates the position.

Such slots provide a water flow guide along a temporarily enlarged hydrophilic profile that enhances the Bernoulli effect of a wing, comparable to known mechanisms in aircraft wings that offer a greater lift at low speeds of an aircraft.

Such constructions will contribute to efficiency, especially in water with a frequently variable flow rate, such as tidal flow.

The low and faster flow rates can then be optimally utilized in the same rotor concept.

The wheels can be placed horizontally or vertically.

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Embodiment example and calculation: 2 linked rotors, each with 6 rotating wing slats on open aluminum drums (or a similar construction) 12 m x 6 m (or 1 rotor of 24 x 6 m) gives a perpendicular view surface of 144 m2.

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If diffusers can locally double a given water speed of 1.3 m / s (= 4.7 km / h, a current speed prevailing on the large Dutch rivers), this gives (with selected / estimated rotor efficiency 49% and a mass density of water 832 and A = 144 (see above) with effectively a local water speed of 2.6 m / sec.

The 'power formula' (Pw = 0.5. Η. P. V}. A) is then entered as follows: at P = power (J / s or watt) 10 η = rotor efficiency v = medium speed (water / air) ) in m / sec A = view in flow direction of effective part of rotor in m2 p = mass density of water (kg / m3) ...... = 832 as 0.5 x 832 x 0.49 x 17.576 (= (2 , 6) 3) x 144 ...... 515907 watts, or more than 15 a half megawatt.

At a given water speed of 1.8 m / s (6.5 km / h, or 3.25 knots) this gives a theoretical yield (doubled with diffusers up to 3.6 m / s) of more than one and a half megawatts of the installation described. .

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An advantage of hydropower installations over wind turbines is the predictability of the power source (statistics, almanacs, flow and tide tables, etc.).

In many cases, the power source (river and tidal currents) is more accessible than with, for example, 80 meter high masts, which the self-adjusting rotors (despite all the mechanics and electronics called in only 20% effective) and generator (a 3 Mw generator weighs currently carry 4 tonnes).

The rotors can operate effectively in a narrow range of wind speeds. Diffusers can more easily be placed in a water stream to increase the medium velocity.

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Claims (1)

25 In the text, "floating pressure" instead of "water pressure" must be assumed as the floating medium. ^ 0 3 S A 7 8