RU2044157C1 - Aerohydrodynamic windmill - Google Patents

Abstract

FIELD: wind-electric power engineering; vertical-shaft wind-electric power plants. SUBSTANCE: windmill is multitier structure with at least three vertical blades in each tier hinged on shafts. Each blade is of aerodynamic airfoil statically balanced-out relative to center of axis of revolution offset towards front edge of blade. Blade shafts in each tier are displaced in respect to those of adjacent tiers. Stops engageable with blades are offcentered from axes of revolution of respective blades to windmill shaft by distance smaller than that from front edge to center of blade revolution along airfoil chord. EFFECT: improved design. 7 dwg

Description

 The invention relates to aerohydrodynamic engines that convert the energy of the translational motion of a gas or liquid medium into the rotational motion of the drive shaft of a power machine.

 The known aerohydrodynamic engine comprises a vertical shaft, vertical axes connected to the shaft, blades pivotally mounted on the axes, and stops interacting with the blades, restricting the rotation of the blades around the axes. Under the influence of the free-stream pressure, the blades located, for example, to the left of the plane passing through the shaft and the free-stream velocity vector occupy the position in which they experience the greatest aero-hydrodynamic resistance (due to the stops restricting their rotation), and the blades located to the right of the above-mentioned plane, due to their vane properties, stand along the flow, experiencing minimal aerohydrodynamic resistance, as a result of which a rotation moment is created on the shaft, which can be used used to drive various mechanisms.

The disadvantage of the described device is the unevenness of the torque created by it, due to the fact that the blades move in a circular path around the shaft and change their angular position relative to the incoming flow and accordingly change the developed torque according to a law close to sinusoidal from zero at the moment of entry of the blade in contact with the stop, when the blade is still parallel to the incoming flow, to the maximum at the moment when the blade occupies a position perpendicular to the flow, and then the mind ensheniem zero to blade exit point of contact with the stop and reversal 180 due ^to its properties parallel to the flow vane.

 If there are only two blades in the aerohydrodynamic engine twice in one full revolution, a position of unstable equilibrium occurs, in which both blades are located strictly in the plane of the shaft and the velocity vector of the incoming flow. The way out of this position is possible only due to the inertia of the rotating parts of the engine or a change in the direction of flow. In this position, the rotational moment is zero, and if there are sufficient friction or braking forces in the mechanism driven by the aero-hydrodynamic engine, it may stop. The unevenness of the torque created by a two-blade engine of this type is 100%. With an increase in the number of blades, the position of unstable equilibrium is eliminated, and the unevenness of the torque changes according to a rather complicated law.

 For a three-blade design, for which the phenomenon of interference and “shadowing” of adjacent blades can be neglected, it is easy to show by graphically adding sinusoids characterizing the developed torque that its unevenness is about 13% per one full revolution of the shaft.

 Another, albeit less significant drawback is the increased dimensions and weight of the structure, associated with the presence of stops located at a distance greater than the distance from the shaft to the axes of the blades, which results in increased inertia of the structure and a decrease in power taken from a unit mass of the engine structure.

 The aim of the invention is to eliminate these drawbacks and to obtain a more stable torque on the shaft and a higher specific power.

 This is achieved by the fact that the aerohydrodynamic engine, comprising a vertical shaft, vertical axes connected to the shaft, blades pivotally mounted on the axes, and stops interacting with the blades, restricting the rotation of the blades around the axes, is multi-tier with at least three blades placed in each tier, each blade is made of an aerodynamic profile and is statically balanced relative to the center of the axis of rotation, shifted towards the front edge of the blade, while the axis of the blades of each tier are shifted in relation the axes of adjacent tiers by an angle equal to the quotient of dividing the angle between the tier axes by the total number of tiers, the stops are offset from the center of rotation axes of the respective blades to the shaft by an amount less than the distance from the leading edge to the center of rotation of the blade along the profile chord.

 In FIG. 1 shows a general view of a two-tier aerohydrodynamic engine; in FIG. 2 the same, vertical projection; in FIG. 3 is a diagram of the rotational moment created by a two-tier three-blade structure; in FIG. 4 is a diagram of the torque generated by a single-tier two-blade structure; in FIG. 5 aerohydrodynamic engine in the area of the stop; in FIG. 6 the same, vertical projection; in FIG. 7 is a flow diagram.

Aerohydrodynamic engine contains a shaft 1, the blades 2 and 2 ^' , the axis of the blades 3 and 3 ^' and the stops 4 and 4 ^' .

Shaft 1 is located vertically to the surface of the earth and perpendicular to the velocity vector V _~ . The blades 2 and 2 'have the same dimensions and are made in the form of two parts unequal in size and weight, statically balanced relative to their axes 3 and 3 ^' . Furthermore, as shown in FIG. 6, the distance A from the leading edge of the blade to the center of the axis of rotation along the chord of the profile exceeds the distance B between the axis of the blade 3 or 3 ^' and the stop 4 or 4 ^' .

 The stops and axes of the lower tier are offset relative to the stops and axes of the upper tier by an angle a equal to the quotient of dividing the angle between the axes of the tier b by the total number of tiers n, i.e. and b / n.

 The number of blades in each tier is the same and mainly equal to three.

The action of the device is illustrated by a diagram of the rotational moment M _BP created by the blades as a function of the angle of rotation of the shaft Θ shown in FIG. 3, which, for simplicity, shows a diagram of the torque generated by the two-tier three-blade design of the aerohydrodynamic engine for one full revolution of the shaft. For comparison, in FIG. 4 is a diagram of the moment created by a single-tier two-blade structure also for one full revolution of the shaft.

As can be seen from FIG. 3, the dependence characterizing the rotational moment created by the two-tier three-bladed structure is the result of the addition of two half-sine waves displaced in phase by an angle of 120 ^° / 2 ° 60 ^° .

The result of the graphical addition of these half-sinusoids gives the magnitude of the non-uniformity of the torque ΔM _BP = (M _max M _min ) / M _max } x 100% equal to ≈7%
The same for a two-bladed single-tier structure (see Fig. 4), gives a magnitude of the unevenness of the torque equal to 100%
Thus, the proposed technical solution of the aerohydrodynamic engine provides a more stable torque on the shaft. At the same time, by dividing the area of the blade at a given amount of rotational moment or power, which the aerohydrodynamic engine should develop, into several smaller blades having the same total area, as well as their spacing into several tiers, it allows to reduce the wind load on the supporting structural elements, such as the axis of the blades, stops, shaft, i.e. Allows to generally facilitate the design and increase the specific power.

When the incident flow acts on the blades 2 and 2 ', the latter begin to rotate around their own axes 3 and 3', occupying a position in which the part of the blades located to the left of the velocity vector V _~ with their rear sides touches the stops 4 and 4 ', and part of the blades, to the right of the vector V _~ rises in the direction of flow. As a result of such rotations of the blades around the axes, the aero-hydrodynamic resistance of the blades located on the left increases to a maximum, while the resistance of the blades located to the right of the plane in which the vector V _~ and the shaft become minimal. When one of the blades located in the left part passes through the plane of the vector V _~ and the shaft (point B in Fig. 7) during the rotation, the incoming flow begins to act on this blade from the back side and rotates it along the arrow around its own axis 180 ^° until the short part of the blade A comes into contact with the stop. As you continue to move along a circular path, the blade in question moves away from the stop and rises in the direction of flow. This process is repeated when each subsequent blade passes through point B. When changing the azimuthal direction of the incoming flow, the described design acts similarly to the prototype, while the established ratio of sizes A and B excludes the possibility of rotation of the blades around the axes by 360 ^° and the associated change in the direction of rotation of the motor shaft .

 The described technical solution allows to simplify the design, reduce the size of the bearing parts and their passive mass, thereby providing a higher specific power developed by an aerohydrodynamic engine.

Claims (1)

 AEROHYDRODYNAMIC ENGINE containing a vertical shaft, vertical axes connected to the shaft, blades pivotally mounted on the axes, and stops interacting with the blades, restricting the rotation of the blades around the axes, characterized in that the engine is multi-tiered with at least three blades placed in each tier, each blade is made of an aerodynamic profile and is statically balanced relative to the center of the axis of rotation, shifted towards the front edge of the blade, while the axis of the blades of each tier are shifted about relative to the axes of the adjacent tier by an angle equal to the quotient of the angle between the axes of tiers on the total number of tiers, the stops are offset from the rotation center axes of the corresponding blade to the shaft by an amount less than the distance from the leading edge to the blade center of rotation of the chord of the profile.

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